diff --git a/1-enrich-with-datacite/all_datacite_clients_for_uga.csv b/1-enrich-with-datacite/all_datacite_clients_for_uga.csv
index 9a64976a668cef2606f6e26929bba06ffe6050d7..e70c0cd2a94a01dfe96131eef59bf6fa1b9dcec1 100644
--- a/1-enrich-with-datacite/all_datacite_clients_for_uga.csv
+++ b/1-enrich-with-datacite/all_datacite_clients_for_uga.csv
@@ -1,35 +1,43 @@
-client,count
-cern.zenodo,936
-inist.sshade,468
-inist.osug,238
-figshare.ars,183
-dryad.dryad,156
-inist.resif,78
-inist.persyval,55
-rdg.prod,45
-inist.humanum,28
-figshare.sage,16
-mcdy.dohrmi,12
-rg.rg,4
-vqpf.dris,3
-tib.gfzbib,3
-iris.iris,3
-ugraz.unipub,2
-inist.epure,2
-bl.nerc,2
-tib.repod,2
-estdoi.ttu,1
-inist.omp,1
-tib.gfz,1
-edi.edi,1
-inist.opgc,1
-bl.iita,1
-ardcx.nci,1
-umass.uma,1
-crui.ingv,1
-bl.mendeley,1
-ethz.zora,1
-inist.ird,1
-inist.eost,1
-ihumi.pub,1
-tug.openlib,1
+client,count,name,year,url
+cern.zenodo,983,Zenodo,2013,https://zenodo.org/
+inist.sshade,748,Solid Spectroscopy Hosting Architecture of Databases and Expertise,2019,https://www.sshade.eu/
+figshare.ars,273,figshare Academic Research System,2016,http://figshare.com/
+inist.osug,238,Observatoire des Sciences de l'Univers de Grenoble,2014,http://doi.osug.fr
+dryad.dryad,157,DRYAD,2018,https://datadryad.org
+inist.resif,120,Réseau sismologique et géodésique français,2014,https://www.resif.fr/
+inist.persyval,55,PERSYVAL-Lab : Pervasive Systems and Algorithms Lab,2016,
+rdg.prod,47,Recherche Data Gouv France,2022,https://recherche.data.gouv.fr/en
+inist.humanum,34,Huma-Num,2020,https://nakala.fr
+figshare.sage,16,figshare SAGE Publications,2018,
+mcdy.dohrmi,12,dggv-e-publications,2020,https://www.dggv.de/publikationen/dggv-e-publikationen.html
+uqtr.mesxqq,7,Collection numérique (UQTR),2023,https://collection-numerique.uqtr.ca/
+gfz.iugg2023,6,IUGG 2023,2022,https://gfzpublic.gfz-potsdam.de
+rg.rg,4,ResearchGate,2016,https://www.researchgate.net/search/data
+iris.iris,3,Incorporated Research Institutions for Seismology,2018,http://www.iris.edu/hq/
+vqpf.dris,3,Direction des ressources et de l'information scientifique,2021,
+tib.gfzbib,3,GFZpublic,2011,https://gfzpublic.gfz-potsdam.de
+inist.epure,2,Éditions et presses universitaires de Reims,2020,
+bl.nerc,2,NERC Environmental Data Service,2011,https://eds.ukri.org
+jbru.eso,2,Espaces et Sociétés,2021,
+tib.repod,2,RepOD,2015,
+ugraz.unipub,2,unipub,2019,http://unipub.uni-graz.at
+crui.ingv,1,Istituto Nazionale di Geofisica e Vulcanologia (INGV),2013,http://data.ingv.it/
+inist.omp,1,Observatoire Midi-Pyrénées,2011,
+tib.gfz,1,GFZ Data Services,2011,https://dataservices.gfz-potsdam.de/portal/
+edi.edi,1,Environmental Data Initiative,2017,https://portal.edirepository.org/nis/home.jsp
+inist.mshsud,1,NumeRev,2019,https://www.projet.numerev.com/
+jbru.idees,1,"IDEES : Identité et Différenciation de l'Espace, de l'Environnement et des Sociétés",2021,http://umr-idees.fr/
+inist.opgc,1,Observatoire de Physique du Globe de Clermont-Ferrand,2017,
+bl.iita,1,International Institute of Tropical Agriculture datasets,2017,http://data.iita.org/
+ardcx.nci,1,National Computational Infrastructure,2020,
+umass.uma,1,University of Massachusetts (UMass) Amherst,2018,https://scholarworks.umass.edu/
+bl.mendeley,1,Mendeley Data,2015,https://data.mendeley.com/
+ethz.zora,1,"Universität Zürich, ZORA",2013,https://www.zora.uzh.ch/
+psnc.uwr,1,Uniwersytet Wrocławski,2019,
+inist.utc,1,Université de technologie de Compiègne,2019,https://www.utc.fr/
+inist.ird,1,IRD,2016,
+inist.eost,1,Ecole et Observatoire des Sciences de la Terre,2017,https://eost.unistra.fr/en/
+ihumi.pub,1,IHU Méditerranée Infection,2020,
+arxiv.content,1,arXiv,2021,
+estdoi.ttu,1,TalTech,2019,https://digikogu.taltech.ee
+tug.openlib,1,TU Graz OPEN Library,2020,https://openlib.tugraz.at/
diff --git a/1-enrich-with-datacite/nb-dois.txt b/1-enrich-with-datacite/nb-dois.txt
new file mode 100644
index 0000000000000000000000000000000000000000..194df75887a801ab0cd58dc7a2b18a622464e2b2
--- /dev/null
+++ b/1-enrich-with-datacite/nb-dois.txt
@@ -0,0 +1 @@
+2739
\ No newline at end of file
diff --git a/2-produce-graph/hist-evol-datasets-per-repo.png b/2-produce-graph/hist-evol-datasets-per-repo.png
index 0670ce4e5e43ff36671afebbe633450d96dca80e..d6ebf570cf1ec06f17fc7a4641bb45888096c4b9 100644
Binary files a/2-produce-graph/hist-evol-datasets-per-repo.png and b/2-produce-graph/hist-evol-datasets-per-repo.png differ
diff --git a/2-produce-graph/hist-quantity-year-type.png b/2-produce-graph/hist-quantity-year-type.png
index 99d24a8ae00143d51ded36bbc05f306c5fd59fe5..4089309c85685ffe00404dc418f43115b760f2fe 100644
Binary files a/2-produce-graph/hist-quantity-year-type.png and b/2-produce-graph/hist-quantity-year-type.png differ
diff --git a/2-produce-graph/pie--datacite-client.png b/2-produce-graph/pie--datacite-client.png
index 1cc02841c6f228a15381888235cf247ed2d6e462..a8702990dfa578ed86b3ec8be98c44f4ac64ecf9 100644
Binary files a/2-produce-graph/pie--datacite-client.png and b/2-produce-graph/pie--datacite-client.png differ
diff --git a/2-produce-graph/pie--datacite-type.png b/2-produce-graph/pie--datacite-type.png
index 24a3c75ae115a37691b3174d42ae4d4d0ca31d89..6d106ec94a0eaa7c864a6bc1f7b644898230bc62 100644
Binary files a/2-produce-graph/pie--datacite-type.png and b/2-produce-graph/pie--datacite-type.png differ
diff --git a/dois-uga.csv b/dois-uga.csv
index 653aaef6c66fbece8430d2e3bcb7cc6229bff674..2ceb665e2d5a8a9e6198833c349533e0e5885cf8 100644
--- a/dois-uga.csv
+++ b/dois-uga.csv
@@ -5243,3 +5243,1560 @@ Le support .pdf qui intègre les ressources utilisées pour créer l'atelier et
 ,,RESIF - Réseau Sismologique et géodésique Français,2017.0,en,Dataset,"Open Access,Creative Commons Attribution 4.0 International","Temporary seismic experiments in the Pyrenees and neighbouring areas. Goal: seismic imaging of the lithospheric structure. Backbone: ~45 broadband stations in a 2-D array with ~60 km spacing deployed for ~2.5 years in the Northern side (French side) of the Pyrenees and along the coast of the Bay of Biscay. Sensors: mostly STS-2 and a few CMG3-ESP. Digitizers: mostly Nanometrics Taurus and a few Agecodagis Kephren. The dataset also includes three profiles across the Pyrenees with 20-30 stations each, deployed for 1 year each, 5-7 km interstation spacing. Sensors: Güralp CMG40-T. Digitizers: Nanometrics Taurus.",mds,True,findable,0.0,0.0,0.0,3.0,0.0,2015-04-03T08:27:49.000Z,2015-04-03T08:27:49.000Z,inist.resif,vcob,"Pyrenees,Seismic imaging,Lithospheric structure","[{'subject': 'Pyrenees'}, {'subject': 'Seismic imaging'}, {'subject': 'Lithospheric structure'}]","['160 stations, 2500 Gb']","['Miniseed data data', 'stationXML metadata']"
 ,,SSHADE/GhoSST (OSUG Data Center),2023.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",We measured the reflectance spectra (from 1 to 25 µm) and emissivity (from *** to ***) of powders of olivine sub-µm grains mixed with KBr.,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-02-08T09:15:16.000Z,2023-02-08T09:15:16.000Z,inist.sshade,mgeg,"mineral,laboratory,natural terrestrial,nesosilicate,Olivine Forsterite,tektosilicate,Quartz,solid,commercial,bromide,KBr,laboratory measurement,bidirectional reflection,macroscopic,NIR,Near-Infrared,MIR,Mid-Infrared,reflectance factor,thermal emissivity","[{'subject': 'mineral'}, {'subject': 'laboratory'}, {'subject': 'natural terrestrial'}, {'subject': 'nesosilicate'}, {'subject': 'Olivine Forsterite'}, {'subject': 'tektosilicate'}, {'subject': 'Quartz'}, {'subject': 'solid'}, {'subject': 'commercial'}, {'subject': 'bromide'}, {'subject': 'KBr'}, {'subject': 'laboratory measurement'}, {'subject': 'bidirectional reflection'}, {'subject': 'macroscopic'}, {'subject': 'NIR'}, {'subject': 'Near-Infrared'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'reflectance factor'}, {'subject': 'thermal emissivity'}]",['6 spectra'],['ASCII']
 ,,SSHADE/BANDLIST (OSUG Data Center),2023.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",MIR-FIR Raman bandlist of synthetic $\alpha-Na_2Ca(CO_3)_2$ (Nyerereite) at 295K,mds,True,findable,0.0,0.0,3.0,0.0,0.0,2023-09-08T07:10:41.000Z,2023-09-08T07:10:42.000Z,inist.sshade,mgeg,"$Na_2Ca(CO_3)_2$ - phase alpha,Sodium cation,Calcium cation,Carbonate anion,alpha Dinatrium calcium carbonate,$\alpha-Na_2Ca(CO_3)_2$,Sodium(1+) cation,Calcium(2+) cation,17341-25-2,14127-61-8,Na+,Ca2+,(CO3)2-,Na2Ca(CO3)2,normal salt,normal salts,carbonate,Raman scattering,FIR,MIR,band frequency,band width,band intensity,transition and vibration modes","[{'subject': '$Na_2Ca(CO_3)_2$ - phase alpha', 'subjectScheme': 'name'}, {'subject': 'Sodium cation', 'subjectScheme': 'name'}, {'subject': 'Calcium cation', 'subjectScheme': 'name'}, {'subject': 'Carbonate anion', 'subjectScheme': 'name'}, {'subject': 'alpha Dinatrium calcium carbonate', 'subjectScheme': 'name'}, {'subject': '$\\alpha-Na_2Ca(CO_3)_2$', 'subjectScheme': 'name'}, {'subject': 'Sodium(1+) cation', 'subjectScheme': 'IUPAC name'}, {'subject': 'Calcium(2+) cation', 'subjectScheme': 'IUPAC name'}, {'subject': '17341-25-2', 'subjectScheme': 'CAS number'}, {'subject': '14127-61-8', 'subjectScheme': 'CAS number'}, {'subject': 'Na+', 'subjectScheme': 'formula'}, {'subject': 'Ca2+', 'subjectScheme': 'formula'}, {'subject': '(CO3)2-', 'subjectScheme': 'formula'}, {'subject': 'Na2Ca(CO3)2', 'subjectScheme': 'formula'}, {'subject': 'normal salt', 'subjectScheme': 'class'}, {'subject': 'normal salts', 'subjectScheme': 'class'}, {'subject': 'carbonate', 'subjectScheme': 'compound type'}, {'subject': 'Raman scattering', 'subjectScheme': 'variables'}, {'subject': 'FIR', 'subjectScheme': 'variables'}, {'subject': 'MIR', 'subjectScheme': 'variables'}, {'subject': 'band frequency', 'subjectScheme': 'variables'}, {'subject': 'band width', 'subjectScheme': 'variables'}, {'subject': 'band intensity', 'subjectScheme': 'variables'}, {'subject': 'transition and vibration modes', 'subjectScheme': 'variables'}]",,['ASCII']
+10.6084/m9.figshare.20080019,Views Evolution 5 Minutes Frequency,figshare,2022.0,,Dataset,Creative Commons Attribution 4.0 International,"This dataset contains 1934 videos posted between February 2, 2022 and February 16, 2022. For every video it records the amount of views every 5 minutes.",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2022-06-16T13:46:14.000Z,2022-06-16T13:46:28.000Z,figshare.ars,otjm,"Applications in physical sciences,Complex physical systems","[{'subject': 'Applications in physical sciences'}, {'subject': 'Complex physical systems'}]",['352821547 Bytes'],
+10.26302/sshade/experiment_dt_20170706_002,Fe K edge XAS transmission of natural hematite Fe2O3 at ambient conditions,SSHADE/FAME (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2019-11-15T20:29:57.000Z,2019-11-15T20:29:57.000Z,inist.sshade,mgeg,"solid,commercial,non-oxide ceramic,BN powder,natural terrestrial,oxide-hydroxide,Natural hematite,laboratory measurement,transmission,None,hard X,hard X-rays","[{'subject': 'solid'}, {'subject': 'commercial'}, {'subject': 'non-oxide ceramic'}, {'subject': 'BN powder'}, {'subject': 'natural terrestrial'}, {'subject': 'oxide-hydroxide'}, {'subject': 'Natural hematite'}, {'subject': 'laboratory measurement'}, {'subject': 'transmission'}, {'subject': 'None'}, {'subject': 'hard X'}, {'subject': 'hard X-rays'}]",['1 spectrum'],['ASCII']
+10.26302/sshade/experiment_rb_20130101_003,"Ion irradiation ($He^+$, $Ar^+$) of an Allende meteorite pellet probed by IR spectroscopy in the MIR range",SSHADE/DAYSY (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","Mid-IR spectra of pellet n°2 of the Allende meteorite, with different irradiation spots on the surface.",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2022-05-27T17:03:03.000Z,2022-05-27T17:03:04.000Z,inist.sshade,mgeg,"extraterrestrial,carbonaceous chondrite,CV,complex organic-mineral mix,matrix Allende,complex mineral mix,chondrules Allende,CAIs Allende,laboratory measurement,confocal reflection,micro-imaging,MIR,Mid-Infrared,reflectance factor","[{'subject': 'extraterrestrial'}, {'subject': 'carbonaceous chondrite'}, {'subject': 'CV'}, {'subject': 'complex organic-mineral mix'}, {'subject': 'matrix Allende'}, {'subject': 'complex mineral mix'}, {'subject': 'chondrules Allende'}, {'subject': 'CAIs Allende'}, {'subject': 'laboratory measurement'}, {'subject': 'confocal reflection'}, {'subject': 'micro-imaging'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'reflectance factor'}]",['3 spectra'],['ASCII']
+10.26302/sshade/bandlist_raman_shortite,Raman bandlist of natural Shortite,SSHADE/BANDLIST (OSUG Data Center),2023.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",MIR-FIR Raman bandlist of natural Shortite at 295K,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-09-03T17:36:15.000Z,2023-09-03T17:36:16.000Z,inist.sshade,mgeg,"Shortite,Sodium cation,Calcium cation,Carbonate anion,Sodium(1+) cation,Calcium(2+) cation,17341-25-2,14127-61-8,Na+,Ca2+,(CO3)2-,Na2Ca2(CO3)3,Shortite,non-silicate mineral,carbonate,carbonates, nitrates, borates,anhydrous carbonates,-Shortite- group,14.04.01.01,05.AC.25,Raman scattering,FIR,MIR,band frequency,band width,band intensity,transition and vibration modes","[{'subject': 'Shortite', 'subjectScheme': 'name'}, {'subject': 'Sodium cation', 'subjectScheme': 'name'}, {'subject': 'Calcium cation', 'subjectScheme': 'name'}, {'subject': 'Carbonate anion', 'subjectScheme': 'name'}, {'subject': 'Sodium(1+) cation', 'subjectScheme': 'IUPAC name'}, {'subject': 'Calcium(2+) cation', 'subjectScheme': 'IUPAC name'}, {'subject': '17341-25-2', 'subjectScheme': 'CAS number'}, {'subject': '14127-61-8', 'subjectScheme': 'CAS number'}, {'subject': 'Na+', 'subjectScheme': 'formula'}, {'subject': 'Ca2+', 'subjectScheme': 'formula'}, {'subject': '(CO3)2-', 'subjectScheme': 'formula'}, {'subject': 'Na2Ca2(CO3)3', 'subjectScheme': 'formula'}, {'subject': 'Shortite', 'subjectScheme': 'IMA name'}, {'subject': 'non-silicate mineral', 'subjectScheme': 'mineral class'}, {'subject': 'carbonate', 'subjectScheme': 'compound type'}, {'subject': 'carbonates, nitrates, borates', 'subjectScheme': 'Dana class'}, {'subject': 'anhydrous carbonates', 'subjectScheme': 'Dana class'}, {'subject': '-Shortite- group', 'subjectScheme': 'Dana group'}, {'subject': '14.04.01.01', 'subjectScheme': 'Dana code'}, {'subject': '05.AC.25', 'subjectScheme': 'Strunz code'}, {'subject': 'Raman scattering', 'subjectScheme': 'variables'}, {'subject': 'FIR', 'subjectScheme': 'variables'}, {'subject': 'MIR', 'subjectScheme': 'variables'}, {'subject': 'band frequency', 'subjectScheme': 'variables'}, {'subject': 'band width', 'subjectScheme': 'variables'}, {'subject': 'band intensity', 'subjectScheme': 'variables'}, {'subject': 'transition and vibration modes', 'subjectScheme': 'variables'}]",,['ASCII']
+10.26302/sshade/experiment_im_20120926_001,Co K edge XAS transmission and XAS fluorescence and XAS HERFD of Co oxides and salts for the study of Co doping in maghemite nanoparticles,SSHADE/FAME (OSUG Data Center),2019.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",Varying the Co environment and adapting the observation mode as a function of the Co content,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2019-12-05T13:34:06.000Z,2019-12-05T13:34:06.000Z,inist.sshade,mgeg,"solid,commercial,non-oxide ceramic,BN powder,nitrate,Co(II)-nitrate hexahydrate,oxide-hydroxide,cobalt oxide Co(II,III),cyanide,potassium hexacyanocobaltate(III),laboratory,oxide,Aluminum oxide,elemental solid,Cobalt,Zinc oxide,tectosilicate,Sol-gel silica,Maghemite nanoparticles,laboratory measurement,transmission,None,hard X,hard X-rays,fluorescence emission","[{'subject': 'solid'}, {'subject': 'commercial'}, {'subject': 'non-oxide ceramic'}, {'subject': 'BN powder'}, {'subject': 'nitrate'}, {'subject': 'Co(II)-nitrate hexahydrate'}, {'subject': 'oxide-hydroxide'}, {'subject': 'cobalt oxide Co(II,III)'}, {'subject': 'cyanide'}, {'subject': 'potassium hexacyanocobaltate(III)'}, {'subject': 'laboratory'}, {'subject': 'oxide'}, {'subject': 'Aluminum oxide'}, {'subject': 'elemental solid'}, {'subject': 'Cobalt'}, {'subject': 'Zinc oxide'}, {'subject': 'tectosilicate'}, {'subject': 'Sol-gel silica'}, {'subject': 'Maghemite nanoparticles'}, {'subject': 'laboratory measurement'}, {'subject': 'transmission'}, {'subject': 'None'}, {'subject': 'hard X'}, {'subject': 'hard X-rays'}, {'subject': 'fluorescence emission'}]",['8 spectra'],['ASCII']
+10.26302/sshade/bandlist_raman_norsethite,Raman bandlist of Norsethite,SSHADE/BANDLIST (OSUG Data Center),2023.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",MIR-FIR Raman bandlist of Norsethite at 295K,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-09-06T08:21:01.000Z,2023-09-06T08:21:01.000Z,inist.sshade,mgeg,"Norsethite,Barium cation,Magnesium(II) cation,Carbonate anion,Barium(2+) cation,Magnesium(2+) cation,22541-12-4,22537-22-0,Ba2+,Mg2+,(CO3)2-,BaMg(CO3)2,Norsethite,non-silicate mineral,carbonate,carbonates, nitrates, borates,anhydrous carbonates,Norsethite group,14.02.02.01,05.AB.30,Raman scattering,FIR,MIR,band frequency,band width,band intensity,transition and vibration modes","[{'subject': 'Norsethite', 'subjectScheme': 'name'}, {'subject': 'Barium cation', 'subjectScheme': 'name'}, {'subject': 'Magnesium(II) cation', 'subjectScheme': 'name'}, {'subject': 'Carbonate anion', 'subjectScheme': 'name'}, {'subject': 'Barium(2+) cation', 'subjectScheme': 'IUPAC name'}, {'subject': 'Magnesium(2+) cation', 'subjectScheme': 'IUPAC name'}, {'subject': '22541-12-4', 'subjectScheme': 'CAS number'}, {'subject': '22537-22-0', 'subjectScheme': 'CAS number'}, {'subject': 'Ba2+', 'subjectScheme': 'formula'}, {'subject': 'Mg2+', 'subjectScheme': 'formula'}, {'subject': '(CO3)2-', 'subjectScheme': 'formula'}, {'subject': 'BaMg(CO3)2', 'subjectScheme': 'formula'}, {'subject': 'Norsethite', 'subjectScheme': 'IMA name'}, {'subject': 'non-silicate mineral', 'subjectScheme': 'mineral class'}, {'subject': 'carbonate', 'subjectScheme': 'compound type'}, {'subject': 'carbonates, nitrates, borates', 'subjectScheme': 'Dana class'}, {'subject': 'anhydrous carbonates', 'subjectScheme': 'Dana class'}, {'subject': 'Norsethite group', 'subjectScheme': 'Dana group'}, {'subject': '14.02.02.01', 'subjectScheme': 'Dana code'}, {'subject': '05.AB.30', 'subjectScheme': 'Strunz code'}, {'subject': 'Raman scattering', 'subjectScheme': 'variables'}, {'subject': 'FIR', 'subjectScheme': 'variables'}, {'subject': 'MIR', 'subjectScheme': 'variables'}, {'subject': 'band frequency', 'subjectScheme': 'variables'}, {'subject': 'band width', 'subjectScheme': 'variables'}, {'subject': 'band intensity', 'subjectScheme': 'variables'}, {'subject': 'transition and vibration modes', 'subjectScheme': 'variables'}]",,['ASCII']
+10.26302/sshade/experiment_ak_20141109_1,Mid-infrared attenuated total reflectance experiment with K+ exchanged less 0.1 μm size fraction of beidellite (SbId-1) equilibrated with D2O vapor under variable relative humidity,SSHADE/LSD (OSUG Data Center),2019.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2022-11-04T08:13:30.000Z,2022-11-04T08:13:31.000Z,inist.sshade,mgeg,"natural terrestrial,phyllosilicate,K-exchanged beidellite SbId-1 size-fraction <0.1 µm,liquid,D2O 99.9 Sigma-Aldrich,laboratory measurement,ATReflection,macroscopic,MIR,Mid-Infrared,corrected ATR absorbance","[{'subject': 'natural terrestrial'}, {'subject': 'phyllosilicate'}, {'subject': 'K-exchanged beidellite SbId-1 size-fraction <0.1 µm'}, {'subject': 'liquid'}, {'subject': 'D2O 99.9 Sigma-Aldrich'}, {'subject': 'laboratory measurement'}, {'subject': 'ATReflection'}, {'subject': 'macroscopic'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'corrected ATR absorbance'}]",['5 spectra'],['ASCII']
+10.26302/sshade/bandlist_abs_ch4_ch4-i,Absorption band list of CH4 in natural solid CH4 (phase I),SSHADE/BANDLIST (OSUG Data Center),2022.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",FIR-MIR-NIR-Vis absorption band list of the isotopes of CH4 in natural solid CH4 (phase I) at 30 and 90 K,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-04-22T06:34:43.000Z,2023-04-22T06:34:43.000Z,inist.sshade,mgeg,"natural CH4 - phase I,Methane,Methane I ice,CH4-I,Methane,74-82-8,CH4,non polar molecular solid,molecular solids with apolar molecules,organic molecular solid,absorption,NIR,MIR,FIR,band frequency,band width,band intensity,transition and vibration modes","[{'subject': 'natural CH4 - phase I', 'subjectScheme': 'name'}, {'subject': 'Methane', 'subjectScheme': 'name'}, {'subject': 'Methane I ice', 'subjectScheme': 'name'}, {'subject': 'CH4-I', 'subjectScheme': 'name'}, {'subject': 'Methane', 'subjectScheme': 'IUPAC name'}, {'subject': '74-82-8', 'subjectScheme': 'CAS number'}, {'subject': 'CH4', 'subjectScheme': 'formula'}, {'subject': 'non polar molecular solid', 'subjectScheme': 'class'}, {'subject': 'molecular solids with apolar molecules', 'subjectScheme': 'class'}, {'subject': 'organic molecular solid', 'subjectScheme': 'compound type'}, {'subject': 'absorption', 'subjectScheme': 'var'}, {'subject': 'NIR', 'subjectScheme': 'var'}, {'subject': 'MIR', 'subjectScheme': 'var'}, {'subject': 'FIR', 'subjectScheme': 'var'}, {'subject': 'band frequency', 'subjectScheme': 'var'}, {'subject': 'band width', 'subjectScheme': 'var'}, {'subject': 'band intensity', 'subjectScheme': 'var'}, {'subject': 'transition and vibration modes', 'subjectScheme': 'var'}]",,['ASCII']
+10.5281/zenodo.10440364,Replication package for article: From low-level fault modeling (of a pipeline attack) to a proven hardening scheme,Zenodo,2024.0,en,Software,,"This software package is the Docker image of a project about protecting RISC-V processors against certain low-level fault attacks. It mainly contains a modified LLVM, GNU binutils, QEMU, and test scripts.
+
+Project repository from which this image is built: https://gricad-gitlab.univ-grenoble-alpes.fr/michelse/fetch-skips-hardening
+
+Instructions for using this software and reproducing results: https://gricad-gitlab.univ-grenoble-alpes.fr/michelse/fetch-skips-hardening/-/blob/main/README.md?ref_type=heads
+
+ ",api,True,findable,0.0,0.0,0.0,0.0,0.0,2024-01-04T00:26:33.000Z,2024-01-04T00:26:34.000Z,cern.zenodo,cern,"Compilation,Fault models,Hardware security","[{'subject': 'Compilation'}, {'subject': 'Fault models'}, {'subject': 'Hardware security'}]",,
+10.6084/m9.figshare.c.6853693,Obstructive sleep apnea: a major risk factor for COVID-19 encephalopathy?,figshare,2023.0,,Collection,Creative Commons Attribution 4.0 International,"Abstract Background This study evaluates the impact of high risk of obstructive sleep apnea (OSA) on coronavirus disease 2019 (COVID-19) acute encephalopathy (AE). Methods Between 3/1/2020 and 11/1/2021, 97 consecutive patients were evaluated at the Geneva University Hospitals with a neurological diagnosis of COVID-19 AE. They were divided in two groups depending on the presence or absence of high risk for OSA based on the modified NOSAS score (mNOSAS, respectively ≥ 8 and < 8). We compared patients’ characteristics (clinical, biological, brain MRI, EEG, pulmonary CT). The severity of COVID-19 AE relied on the RASS and CAM scores. Results Most COVID-19 AE patients presented with a high mNOSAS, suggesting high risk of OSA (> 80%). Patients with a high mNOSAS had a more severe form of COVID-19 AE (84.8% versus 27.8%), longer mean duration of COVID-19 AE (27.9 versus 16.9 days), higher mRS at discharge (≥ 3 in 58.2% versus 16.7%), and increased prevalence of brain vessels enhancement (98.1% versus 20.0%). High risk of OSA was associated with a 14 fold increased risk of developing a severe COVID-19 AE (OR = 14.52). Discussion These observations suggest an association between high risk of OSA and COVID-19 AE severity. High risk of OSA could be a predisposing factor leading to severe COVID-19 AE and consecutive long-term sequalae.",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-09-27T03:26:12.000Z,2023-09-27T03:26:13.000Z,figshare.ars,otjm,"Biophysics,Medicine,Cell Biology,Neuroscience,Physiology,FOS: Biological sciences,Pharmacology,Biotechnology,Sociology,FOS: Sociology,Immunology,FOS: Clinical medicine,Cancer,Mental Health,Virology","[{'subject': 'Biophysics'}, {'subject': 'Medicine'}, {'subject': 'Cell Biology'}, {'subject': 'Neuroscience'}, {'subject': 'Physiology'}, {'subject': 'FOS: Biological sciences', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': 'Pharmacology'}, {'subject': 'Biotechnology'}, {'subject': 'Sociology'}, {'subject': 'FOS: Sociology', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': 'Immunology'}, {'subject': 'FOS: Clinical medicine', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': 'Cancer'}, {'subject': 'Mental Health'}, {'subject': 'Virology'}]",,
+10.26302/sshade/bandlist_raman_ankerite,Raman bandlist of natural Ankerite,SSHADE/BANDLIST (OSUG Data Center),2023.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",MIR-FIR Raman bandlist of natural Ankerite (Fe > Mg) at 295K,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-08-26T09:04:37.000Z,2023-08-26T09:04:37.000Z,inist.sshade,mgeg,"Ankerite,Calcium,Iron(II) cation,Magnesium,Manganese(II) cation,Carbonate anion,Calcium,Iron(2+) cation,Magnesium,Manganese(2+) cation,7440-70-2,15438-31-0,7439-95-4,16397-91-4,Ca,Fe2+,Mg,Mn2+,(CO3)2-,Ca(Fe2+,Mg,Mn2+)(CO3)2,Ankerite,non-silicate mineral,carbonate,carbonates, nitrates, borates,anhydrous carbonates,Norsethite Group,14.02.01.02,05.AB.10,Raman scattering,FIR,MIR,band frequency,band width,band intensity,transition and vibration modes","[{'subject': 'Ankerite', 'subjectScheme': 'name'}, {'subject': 'Calcium', 'subjectScheme': 'name'}, {'subject': 'Iron(II) cation', 'subjectScheme': 'name'}, {'subject': 'Magnesium', 'subjectScheme': 'name'}, {'subject': 'Manganese(II) cation', 'subjectScheme': 'name'}, {'subject': 'Carbonate anion', 'subjectScheme': 'name'}, {'subject': 'Calcium', 'subjectScheme': 'IUPAC name'}, {'subject': 'Iron(2+) cation', 'subjectScheme': 'IUPAC name'}, {'subject': 'Magnesium', 'subjectScheme': 'IUPAC name'}, {'subject': 'Manganese(2+) cation', 'subjectScheme': 'IUPAC name'}, {'subject': '7440-70-2', 'subjectScheme': 'CAS number'}, {'subject': '15438-31-0', 'subjectScheme': 'CAS number'}, {'subject': '7439-95-4', 'subjectScheme': 'CAS number'}, {'subject': '16397-91-4', 'subjectScheme': 'CAS number'}, {'subject': 'Ca', 'subjectScheme': 'formula'}, {'subject': 'Fe2+', 'subjectScheme': 'formula'}, {'subject': 'Mg', 'subjectScheme': 'formula'}, {'subject': 'Mn2+', 'subjectScheme': 'formula'}, {'subject': '(CO3)2-', 'subjectScheme': 'formula'}, {'subject': 'Ca(Fe2+,Mg,Mn2+)(CO3)2', 'subjectScheme': 'formula'}, {'subject': 'Ankerite', 'subjectScheme': 'IMA name'}, {'subject': 'non-silicate mineral', 'subjectScheme': 'mineral class'}, {'subject': 'carbonate', 'subjectScheme': 'compound type'}, {'subject': 'carbonates, nitrates, borates', 'subjectScheme': 'Dana class'}, {'subject': 'anhydrous carbonates', 'subjectScheme': 'Dana class'}, {'subject': 'Norsethite Group', 'subjectScheme': 'Dana group'}, {'subject': '14.02.01.02', 'subjectScheme': 'Dana code'}, {'subject': '05.AB.10', 'subjectScheme': 'Strunz code'}, {'subject': 'Raman scattering', 'subjectScheme': 'variables'}, {'subject': 'FIR', 'subjectScheme': 'variables'}, {'subject': 'MIR', 'subjectScheme': 'variables'}, {'subject': 'band frequency', 'subjectScheme': 'variables'}, {'subject': 'band width', 'subjectScheme': 'variables'}, {'subject': 'band intensity', 'subjectScheme': 'variables'}, {'subject': 'transition and vibration modes', 'subjectScheme': 'variables'}]",,['ASCII']
+10.26302/sshade/experiment_vc_20070129_001,Vis-NIR reflectance spectra of Iceland sand wetted with water and dried in ambiant air at 38°C,SSHADE/SSTONE (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","In order to investigate the spectral behavior of humidity on sand spectra, we have acquired laboratory reflectance spectra of a sand containing various proportion of water. Water was deposited on a dry sand (previously dried in an oven at 40°C during one night). During the experiment, the sample is then dried, under the sun at 38°C. A spectrum is acquired every 5 minutes with an ASD FieldSpec3FR. This experiment was done on Iceland sand",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-04-22T08:30:27.000Z,2023-04-22T08:30:27.000Z,inist.sshade,mgeg,"laboratory measurement,bidirectional reflection,macroscopic,Vis,Visible,NIR,Near-Infrared,bidirectional reflectance,Amorphous phase,Magnesite,Hematite,Tridymite,Quartz,Augite,Albite,Liquid water,mineral,natural terrestrial,tektosilicate,carbonate,oxide-hydroxide,inosilicate,liquid","[{'subject': 'laboratory measurement', 'subjectScheme': 'main'}, {'subject': 'bidirectional reflection', 'subjectScheme': 'main'}, {'subject': 'macroscopic', 'subjectScheme': 'main'}, {'subject': 'Vis', 'subjectScheme': 'var'}, {'subject': 'Visible', 'subjectScheme': 'var'}, {'subject': 'NIR', 'subjectScheme': 'var'}, {'subject': 'Near-Infrared', 'subjectScheme': 'var'}, {'subject': 'bidirectional reflectance', 'subjectScheme': 'var'}, {'subject': 'Amorphous phase', 'subjectScheme': 'name'}, {'subject': 'Magnesite', 'subjectScheme': 'name'}, {'subject': 'Hematite', 'subjectScheme': 'name'}, {'subject': 'Tridymite', 'subjectScheme': 'name'}, {'subject': 'Quartz', 'subjectScheme': 'name'}, {'subject': 'Augite', 'subjectScheme': 'name'}, {'subject': 'Albite', 'subjectScheme': 'name'}, {'subject': 'Liquid water', 'subjectScheme': 'name'}, {'subject': 'mineral', 'subjectScheme': 'family'}, {'subject': 'natural terrestrial', 'subjectScheme': 'origin'}, {'subject': 'tektosilicate', 'subjectScheme': 'compound type'}, {'subject': 'carbonate', 'subjectScheme': 'compound type'}, {'subject': 'oxide-hydroxide', 'subjectScheme': 'compound type'}, {'subject': 'inosilicate', 'subjectScheme': 'compound type'}, {'subject': 'liquid', 'subjectScheme': 'compound type'}]",['29 spectra'],['ASCII']
+10.6084/m9.figshare.22599664,Additional file 2 of Procalcitonin to reduce exposure to antibiotics and individualise treatment in hospitalised old patients with pneumonia: a randomised study,figshare,2023.0,,Text,Creative Commons Attribution 4.0 International,Additional file 2.,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-04-13T09:42:55.000Z,2023-04-13T09:42:56.000Z,figshare.ars,otjm,"Space Science,Medicine,Immunology,FOS: Clinical medicine,Cancer,111714 Mental Health,FOS: Health sciences,110309 Infectious Diseases","[{'subject': 'Space Science'}, {'subject': 'Medicine'}, {'subject': 'Immunology'}, {'subject': 'FOS: Clinical medicine', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': 'Cancer'}, {'subject': '111714 Mental Health', 'schemeUri': 'http://www.abs.gov.au/ausstats/abs@.nsf/0/6BB427AB9696C225CA2574180004463E', 'subjectScheme': 'FOR'}, {'subject': 'FOS: Health sciences', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': '110309 Infectious Diseases', 'schemeUri': 'http://www.abs.gov.au/ausstats/abs@.nsf/0/6BB427AB9696C225CA2574180004463E', 'subjectScheme': 'FOR'}]",['286856 Bytes'],
+10.6084/m9.figshare.c.6257914,Acute mesenteric ischemia: updated guidelines of the World Society of Emergency Surgery,figshare,2022.0,,Collection,Creative Commons Attribution 4.0 International,"Abstract Acute mesenteric ischemia (AMI) is a group of diseases characterized by an interruption of the blood supply to varying portions of the intestine, leading to ischemia and secondary inflammatory changes. If untreated, this process may progress to life-threatening intestinal necrosis. The incidence is low, estimated at 0.09–0.2% of all acute surgical admissions, but increases with age. Although the entity is an uncommon cause of abdominal pain, diligence is required because if untreated, mortality remains in the range of 50%. Early diagnosis and timely surgical intervention are the cornerstones of modern treatment to reduce the high mortality associated with this entity. The advent of endovascular approaches in parallel with modern imaging techniques is evolving and provides new treatment options. Lastly, a focused multidisciplinary approach based on early diagnosis and individualized treatment is essential. Thus, we believe that updated guidelines from World Society of Emergency Surgery are warranted, in order to provide the most recent and practical recommendations for diagnosis and treatment of AMI.",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2022-10-20T06:32:09.000Z,2022-10-20T06:32:09.000Z,figshare.ars,otjm,"Medicine,Genetics,FOS: Biological sciences,Neuroscience,Biotechnology,80699 Information Systems not elsewhere classified,FOS: Computer and information sciences","[{'subject': 'Medicine'}, {'subject': 'Genetics'}, {'subject': 'FOS: Biological sciences', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': 'Neuroscience'}, {'subject': 'Biotechnology'}, {'subject': '80699 Information Systems not elsewhere classified', 'schemeUri': 'http://www.abs.gov.au/ausstats/abs@.nsf/0/6BB427AB9696C225CA2574180004463E', 'subjectScheme': 'FOR'}, {'subject': 'FOS: Computer and information sciences', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}]",,
+10.26302/sshade/experiment_gv_20181121_001,Ag K edge XAS fluorescence of Ag-GSH 1:1 solution (pH=7.4) at 16K,SSHADE/FAME (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2019-12-05T14:40:14.000Z,2019-12-05T14:40:14.000Z,inist.sshade,mgeg,"laboratory,molecular solid solution,Frozen solution of Ag-GSH 1:1 (pH=7.4), model for digonal AgS2 coordination,laboratory measurement,fluorescence emission,None,hard X,hard X-rays","[{'subject': 'laboratory'}, {'subject': 'molecular solid solution'}, {'subject': 'Frozen solution of Ag-GSH 1:1 (pH=7.4), model for digonal AgS2 coordination'}, {'subject': 'laboratory measurement'}, {'subject': 'fluorescence emission'}, {'subject': 'None'}, {'subject': 'hard X'}, {'subject': 'hard X-rays'}]",['1 spectrum'],['ASCII']
+10.26302/sshade/bandlist_raman_co_alpha-co,Raman band list of CO in natural solid CO (phase alpha),SSHADE/BANDLIST (OSUG Data Center),2021.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",MIR-FIR Raman band list of the isotopes of $CO$ in natural $\alpha-CO$ ice,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-04-21T07:13:51.000Z,2023-04-21T07:13:52.000Z,inist.sshade,mgeg,"natural CO - phase alpha,Carbon monoxide,alpha Carbon Monoxide,$\alpha-CO$,Carbon monoxide,630-08-0,CO,polar molecular solid,molecular solids with polar molecules,inorganic molecular solid,Raman scattering,MIR,FIR,band frequency,band width,band intensity,transition and vibration modes","[{'subject': 'natural CO - phase alpha', 'subjectScheme': 'name'}, {'subject': 'Carbon monoxide', 'subjectScheme': 'name'}, {'subject': 'alpha Carbon Monoxide', 'subjectScheme': 'name'}, {'subject': '$\\alpha-CO$', 'subjectScheme': 'name'}, {'subject': 'Carbon monoxide', 'subjectScheme': 'IUPAC name'}, {'subject': '630-08-0', 'subjectScheme': 'CAS number'}, {'subject': 'CO', 'subjectScheme': 'formula'}, {'subject': 'polar molecular solid', 'subjectScheme': 'class'}, {'subject': 'molecular solids with polar molecules', 'subjectScheme': 'class'}, {'subject': 'inorganic molecular solid', 'subjectScheme': 'compound type'}, {'subject': 'Raman scattering', 'subjectScheme': 'var'}, {'subject': 'MIR', 'subjectScheme': 'var'}, {'subject': 'FIR', 'subjectScheme': 'var'}, {'subject': 'band frequency', 'subjectScheme': 'var'}, {'subject': 'band width', 'subjectScheme': 'var'}, {'subject': 'band intensity', 'subjectScheme': 'var'}, {'subject': 'transition and vibration modes', 'subjectScheme': 'var'}]",,['ASCII']
+10.6084/m9.figshare.c.6250158,Expiratory high-frequency percussive ventilation: a novel concept for improving gas exchange,figshare,2022.0,,Collection,Creative Commons Attribution 4.0 International,"Abstract Background Although high-frequency percussive ventilation (HFPV) improves gas exchange, concerns remain about tissue overdistension caused by the oscillations and consequent lung damage. We compared a modified percussive ventilation modality created by superimposing high-frequency oscillations to the conventional ventilation waveform during expiration only (eHFPV) with conventional mechanical ventilation (CMV) and standard HFPV. Methods Hypoxia and hypercapnia were induced by decreasing the frequency of CMV in New Zealand White rabbits (n = 10). Following steady-state CMV periods, percussive modalities with oscillations randomly introduced to the entire breathing cycle (HFPV) or to the expiratory phase alone (eHFPV) with varying amplitudes (2 or 4 cmH2O) and frequencies were used (5 or 10 Hz). The arterial partial pressures of oxygen (PaO2) and carbon dioxide (PaCO2) were determined. Volumetric capnography was used to evaluate the ventilation dead space fraction, phase 2 slope, and minute elimination of CO2. Respiratory mechanics were characterized by forced oscillations. Results The use of eHFPV with 5 Hz superimposed oscillation frequency and an amplitude of 4 cmH2O enhanced gas exchange similar to those observed after HFPV. These improvements in PaO2 (47.3 ± 5.5 vs. 58.6 ± 7.2 mmHg) and PaCO2 (54.7 ± 2.3 vs. 50.1 ± 2.9 mmHg) were associated with lower ventilation dead space and capnogram phase 2 slope, as well as enhanced minute CO2 elimination without altering respiratory mechanics. Conclusions These findings demonstrated improved gas exchange using eHFPV as a novel mechanical ventilation modality that combines the benefits of conventional and small-amplitude high-frequency oscillatory ventilation, owing to improved longitudinal gas transport rather than increased lung surface area available for gas exchange.",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2022-10-16T03:12:42.000Z,2022-10-16T03:12:43.000Z,figshare.ars,otjm,"Biophysics,Space Science,Medicine,Physiology,FOS: Biological sciences,Biotechnology,Cancer","[{'subject': 'Biophysics'}, {'subject': 'Space Science'}, {'subject': 'Medicine'}, {'subject': 'Physiology'}, {'subject': 'FOS: Biological sciences', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': 'Biotechnology'}, {'subject': 'Cancer'}]",,
+10.26302/sshade/experiment_lb_20191211_001,Fe K edge XAS transmission of bulk CM carbonaceous chondrites,SSHADE/GhoSST+FAME (OSUG Data Center),2020.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",raw and normalized Fe K edge XAS transmission of bulk CM carbonaceous chondrites,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2019-12-13T13:03:09.000Z,2019-12-13T13:03:09.000Z,inist.sshade,mgeg,"solid,commercial,non-oxide ceramic,BN powder,extraterrestrial,carbonaceous chondrite,CM,complex organic-mineral mix,matrix ALH83100 IPAG,complex mineral mix,chondrules ALH83100 IPAG,CAIs ALH83100 IPAG,matrix ALH84029 IPAG,chondrules ALH84029 IPAG,CAIs ALH84029 IPAG,matrix ALH84044 IPAG,chondrules ALH84044 IPAG,CAIs ALH84044 IPAG,matrix DOM08003 IPAG,chondrules DOM08003 IPAG,CAIs DOM08003 IPAG,matrix LAP02333 IPAG,chondrules LAP02333 IPAG,CAIs LAP02333 IPAG,matrix LAP02336 IPAG,chondrules LAP02336 IPAG,CAIs LAP02336 IPAG,matrix LAP03718 IPAG,chondrules LAP03718 IPAG,CAIs EET83355 IPAG,matrix LEW85311 IPAG,chondrules LEW85311 IPAG,CAIs LEW85311 IPAG,matrix LEW85312 IPAG,chondrules LEW85312 IPAG,CAIs LEW85312 IPAG,matrix LEW87022 IPAG,chondrules LEW87022 IPAG,CAIs LEW87022 IPAG,matrix PCA91008 IPAG,chondrules PCA91008 IPAG,CAIs PCA91008 IPAG,matrix LEW90500 IPAG,chondrules LEW90500 IPAG,CAIs LEW90500 IPAG,matrix LON94101 IPAG,chondrules LON94101 IPAG,CAIs LON94101 IPAG,matrix MCY05230 IPAG,chondrules MCY05230 IPAG,CAIs MCY05230 IPAG,matrix MET01070 IPAG,chondrules MET01070 IPAG,CAIs MET01070 IPAG,matrix QUE97990 IPAG,chondrules QUE97990 IPAG,CAIs QUE97990 IPAG,matrix NIGER IPAG,chondrules NIGER IPAG,CAIs NIGER IPAG,matrix Murchison IPAG,chondrules Murchison IPAG,CAIs Murchison IPAG,matrix Murray IPAG,chondrules Murray IPAG,CAIs Murray IPAG,matrix Boriskino IPAG,chondrules Boriskino IPAG,CAIs Boriskino IPAG,matrix Mighei IPAG,chondrules Mighei IPAG,CAIs Mighei IPAG,matrix Banten IPAG,chondrules Banten IPAG,matrix NOGOYA IPAG,chondrules NOGOYA IPAG,CAIs NOGOYA IPAG,ungrouped,matrix ESSEBI IPAG,chondrules ESSEBI IPAG,CAIs ESSEBI IPAG,matrix Cold_Bokkeveld IPAG,chondrules Cold_Bokkeveld IPAG,CAIs Cold_Bokkeveld IPAG,laboratory measurement,transmission,None,hard X,raw,normalized absorbance","[{'subject': 'solid'}, {'subject': 'commercial'}, {'subject': 'non-oxide ceramic'}, {'subject': 'BN powder'}, {'subject': 'extraterrestrial'}, {'subject': 'carbonaceous chondrite'}, {'subject': 'CM'}, {'subject': 'complex organic-mineral mix'}, {'subject': 'matrix ALH83100 IPAG'}, {'subject': 'complex mineral mix'}, {'subject': 'chondrules ALH83100 IPAG'}, {'subject': 'CAIs ALH83100 IPAG'}, {'subject': 'matrix ALH84029 IPAG'}, {'subject': 'chondrules ALH84029 IPAG'}, {'subject': 'CAIs ALH84029 IPAG'}, {'subject': 'matrix ALH84044 IPAG'}, {'subject': 'chondrules ALH84044 IPAG'}, {'subject': 'CAIs ALH84044 IPAG'}, {'subject': 'matrix DOM08003 IPAG'}, {'subject': 'chondrules DOM08003 IPAG'}, {'subject': 'CAIs DOM08003 IPAG'}, {'subject': 'matrix LAP02333 IPAG'}, {'subject': 'chondrules LAP02333 IPAG'}, {'subject': 'CAIs LAP02333 IPAG'}, {'subject': 'matrix LAP02336 IPAG'}, {'subject': 'chondrules LAP02336 IPAG'}, {'subject': 'CAIs LAP02336 IPAG'}, {'subject': 'matrix LAP03718 IPAG'}, {'subject': 'chondrules LAP03718 IPAG'}, {'subject': 'CAIs EET83355 IPAG'}, {'subject': 'matrix LEW85311 IPAG'}, {'subject': 'chondrules LEW85311 IPAG'}, {'subject': 'CAIs LEW85311 IPAG'}, {'subject': 'matrix LEW85312 IPAG'}, {'subject': 'chondrules LEW85312 IPAG'}, {'subject': 'CAIs LEW85312 IPAG'}, {'subject': 'matrix LEW87022 IPAG'}, {'subject': 'chondrules LEW87022 IPAG'}, {'subject': 'CAIs LEW87022 IPAG'}, {'subject': 'matrix PCA91008 IPAG'}, {'subject': 'chondrules PCA91008 IPAG'}, {'subject': 'CAIs PCA91008 IPAG'}, {'subject': 'matrix LEW90500 IPAG'}, {'subject': 'chondrules LEW90500 IPAG'}, {'subject': 'CAIs LEW90500 IPAG'}, {'subject': 'matrix LON94101 IPAG'}, {'subject': 'chondrules LON94101 IPAG'}, {'subject': 'CAIs LON94101 IPAG'}, {'subject': 'matrix MCY05230 IPAG'}, {'subject': 'chondrules MCY05230 IPAG'}, {'subject': 'CAIs MCY05230 IPAG'}, {'subject': 'matrix MET01070 IPAG'}, {'subject': 'chondrules MET01070 IPAG'}, {'subject': 'CAIs MET01070 IPAG'}, {'subject': 'matrix QUE97990 IPAG'}, {'subject': 'chondrules QUE97990 IPAG'}, {'subject': 'CAIs QUE97990 IPAG'}, {'subject': 'matrix NIGER IPAG'}, {'subject': 'chondrules NIGER IPAG'}, {'subject': 'CAIs NIGER IPAG'}, {'subject': 'matrix Murchison IPAG'}, {'subject': 'chondrules Murchison IPAG'}, {'subject': 'CAIs Murchison IPAG'}, {'subject': 'matrix Murray IPAG'}, {'subject': 'chondrules Murray IPAG'}, {'subject': 'CAIs Murray IPAG'}, {'subject': 'matrix Boriskino IPAG'}, {'subject': 'chondrules Boriskino IPAG'}, {'subject': 'CAIs Boriskino IPAG'}, {'subject': 'matrix Mighei IPAG'}, {'subject': 'chondrules Mighei IPAG'}, {'subject': 'CAIs Mighei IPAG'}, {'subject': 'matrix Banten IPAG'}, {'subject': 'chondrules Banten IPAG'}, {'subject': 'matrix NOGOYA IPAG'}, {'subject': 'chondrules NOGOYA IPAG'}, {'subject': 'CAIs NOGOYA IPAG'}, {'subject': 'ungrouped'}, {'subject': 'matrix ESSEBI IPAG'}, {'subject': 'chondrules ESSEBI IPAG'}, {'subject': 'CAIs ESSEBI IPAG'}, {'subject': 'matrix Cold_Bokkeveld IPAG'}, {'subject': 'chondrules Cold_Bokkeveld IPAG'}, {'subject': 'CAIs Cold_Bokkeveld IPAG'}, {'subject': 'laboratory measurement'}, {'subject': 'transmission'}, {'subject': 'None'}, {'subject': 'hard X'}, {'subject': 'raw'}, {'subject': 'normalized absorbance'}]",['48 spectra'],['ASCII']
+10.26302/sshade/bandlist_raman_s2o_ar-matrix,Raman band list of S2O in Ar matrix,SSHADE/BANDLIST (OSUG Data Center),2023.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",MIR Raman band list of the isotopes of $S_2O$ in Ar matrix,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-05-13T13:37:41.000Z,2023-05-13T13:37:41.000Z,inist.sshade,mgeg,"natural $S_2O$ in Ar matrix,Argon,Disulfur monoxide,solid alpha Argon,$\alpha$-phase,Argon,Disulfur monoxide,7440-37-1,20901-21-7,Ar,S2O,tridimentional covalent network solid,molecular solids with apolar molecules,elemental solid,Raman scattering,MIR,band frequency,band width,band intensity,transition and vibration modes","[{'subject': 'natural $S_2O$ in Ar matrix', 'subjectScheme': 'name'}, {'subject': 'Argon', 'subjectScheme': 'name'}, {'subject': 'Disulfur monoxide', 'subjectScheme': 'name'}, {'subject': 'solid alpha Argon', 'subjectScheme': 'name'}, {'subject': '$\\alpha$-phase', 'subjectScheme': 'name'}, {'subject': 'Argon', 'subjectScheme': 'IUPAC name'}, {'subject': 'Disulfur monoxide', 'subjectScheme': 'IUPAC name'}, {'subject': '7440-37-1', 'subjectScheme': 'CAS number'}, {'subject': '20901-21-7', 'subjectScheme': 'CAS number'}, {'subject': 'Ar', 'subjectScheme': 'formula'}, {'subject': 'S2O', 'subjectScheme': 'formula'}, {'subject': 'tridimentional covalent network solid', 'subjectScheme': 'class'}, {'subject': 'molecular solids with apolar molecules', 'subjectScheme': 'class'}, {'subject': 'elemental solid', 'subjectScheme': 'compound type'}, {'subject': 'Raman scattering', 'subjectScheme': 'variables'}, {'subject': 'MIR', 'subjectScheme': 'variables'}, {'subject': 'band frequency', 'subjectScheme': 'variables'}, {'subject': 'band width', 'subjectScheme': 'variables'}, {'subject': 'band intensity', 'subjectScheme': 'variables'}, {'subject': 'transition and vibration modes', 'subjectScheme': 'variables'}]",,['ASCII']
+10.15778/resif.zs2007,SEISMOTANZ'07,RESIF - Réseau Sismologique et géodésique Français,2007.0,en,Other,"Open Access,Creative Commons Attribution 4.0 International","Understanding the forces that initiate continental break-up needs to find sites where magmatism and rifting interact. The thermal structure of the mantle and the crust, the products of partial melting, the position(s) and nature(s) of the inherited structures (cratonic blocks, old lithospheric sutures) play a key role on earthquake genesis and have to be studied into details using different, multi-scale, approaches. The North Tanzanian Divergence (NTD) is one of the unique areas in the world where such objectives can be achieved. Two main questions are driving our project : (1) Is there a characteristic plume impact at depth that modifies the rheology and strength of the lithosphere? (2) Can we identify there, through seismicity and kinematic indicators, the dimension of main active faults and the way deformation is occurring We installed a temporary network of 34 stations for 6 months to follow more precisely the micro-seismicity and infer crust structure.",mds,True,findable,0.0,0.0,0.0,4.0,0.0,2018-04-04T12:43:27.000Z,2018-04-04T12:43:27.000Z,inist.resif,vcob,"North Tanzanian Divergence,East African Rift,Africa,rifting process,micro-seismicity,crust structure","[{'subject': 'North Tanzanian Divergence'}, {'subject': 'East African Rift'}, {'subject': 'Africa'}, {'subject': 'rifting process'}, {'subject': 'micro-seismicity'}, {'subject': 'crust structure'}]",,
+10.26302/sshade/experiment_sb_20210324_001,Optical constants of nonstoichiometric spinels in MIR/FIR,SSHADE/DOCCD (OSUG Data Center),2021.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2021-04-23T06:53:23.000Z,2021-04-23T06:53:24.000Z,inist.sshade,mgeg,"laboratory,oxide-hydroxide,Mg$_{1.01}$Al$_{1.99}$O$_{4}$,Mg$_{0.94}$Al$_{2.04}$O$_{4}$,Mg$_{0.82}$Al$_{2.12}$O$_{4}$,Mg$_{0.73}$Al$_{2.17}$O$_{4}$,Mg$_{0.53}$Al$_{2.31}$O$_{4}$,Mg$_{0.43}$Al$_{2.38}$O$_{4}$,laboratory measurement,specular reflection,macroscopic,MIR,Mid-Infrared,FIR,Far-Infrared,optical constants","[{'subject': 'laboratory'}, {'subject': 'oxide-hydroxide'}, {'subject': 'Mg$_{1.01}$Al$_{1.99}$O$_{4}$'}, {'subject': 'Mg$_{0.94}$Al$_{2.04}$O$_{4}$'}, {'subject': 'Mg$_{0.82}$Al$_{2.12}$O$_{4}$'}, {'subject': 'Mg$_{0.73}$Al$_{2.17}$O$_{4}$'}, {'subject': 'Mg$_{0.53}$Al$_{2.31}$O$_{4}$'}, {'subject': 'Mg$_{0.43}$Al$_{2.38}$O$_{4}$'}, {'subject': 'laboratory measurement'}, {'subject': 'specular reflection'}, {'subject': 'macroscopic'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'FIR'}, {'subject': 'Far-Infrared'}, {'subject': 'optical constants'}]",['6 spectra'],['ASCII']
+10.26302/sshade/experiment_hm_20170913_010,UV/vis optical constants of matrix-isolated carbonaceous nanoparticles condensed in Ar/H2 atmosphere,SSHADE/DOCCD (OSUG Data Center),2019.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2020-04-20T13:08:46.000Z,2020-04-20T13:08:47.000Z,inist.sshade,mgeg,"laboratory,organic molecular solid,Carbonaceous nanoparticles,elemental solid,Solid argon,laboratory measurement,transmission,macroscopic,UV,Ultraviolet,Vis,Visible,optical constants","[{'subject': 'laboratory'}, {'subject': 'organic molecular solid'}, {'subject': 'Carbonaceous nanoparticles'}, {'subject': 'elemental solid'}, {'subject': 'Solid argon'}, {'subject': 'laboratory measurement'}, {'subject': 'transmission'}, {'subject': 'macroscopic'}, {'subject': 'UV'}, {'subject': 'Ultraviolet'}, {'subject': 'Vis'}, {'subject': 'Visible'}, {'subject': 'optical constants'}]",['2 spectra'],['ASCII']
+10.26302/sshade/experiment_gp_20181107_001,Pt L3 edge XAS HERFD and XAS transmission of platinum hydrogensulfide complexes in geological fluids (impact of sulfur on the transfer of noble metals by hydrothermal fluids),SSHADE/FAME (OSUG Data Center),2022.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","Platinum oxide, chloride, sulfide and polysulfide phases; fluorescence and transmission; 25°C 1 bar",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2022-12-13T11:19:51.000Z,2022-12-13T11:19:52.000Z,inist.sshade,mgeg,"solid,commercial,non-oxide ceramic,BN powder,laboratory,sulfide,PtS,PtS2,organic molecular solid,C6H12N2O4Pt,chloride,K2PtCl4,K2PtCl6,(NH4)2Pt(S5)3,oxide,PtO2,laboratory measurement,fluorescence emission,None,hard X,hard X-rays,transmission","[{'subject': 'solid'}, {'subject': 'commercial'}, {'subject': 'non-oxide ceramic'}, {'subject': 'BN powder'}, {'subject': 'laboratory'}, {'subject': 'sulfide'}, {'subject': 'PtS'}, {'subject': 'PtS2'}, {'subject': 'organic molecular solid'}, {'subject': 'C6H12N2O4Pt'}, {'subject': 'chloride'}, {'subject': 'K2PtCl4'}, {'subject': 'K2PtCl6'}, {'subject': '(NH4)2Pt(S5)3'}, {'subject': 'oxide'}, {'subject': 'PtO2'}, {'subject': 'laboratory measurement'}, {'subject': 'fluorescence emission'}, {'subject': 'None'}, {'subject': 'hard X'}, {'subject': 'hard X-rays'}, {'subject': 'transmission'}]",['14 spectra'],['ASCII']
+10.26302/sshade/experiment_sb_20210430_001,Optical constants in the MIR and FIR for an oriented olivine crystal parallel to the three crystallographic axes,SSHADE/DOCCD (OSUG Data Center),2021.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2021-05-10T12:27:40.000Z,2021-05-10T12:27:41.000Z,inist.sshade,mgeg,"natural terrestrial,nesosilicate,Olivine,laboratory measurement,specular reflection,macroscopic,MIR,Mid-Infrared,FIR,Far-Infrared,optical constants","[{'subject': 'natural terrestrial'}, {'subject': 'nesosilicate'}, {'subject': 'Olivine'}, {'subject': 'laboratory measurement'}, {'subject': 'specular reflection'}, {'subject': 'macroscopic'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'FIR'}, {'subject': 'Far-Infrared'}, {'subject': 'optical constants'}]",['3 spectra'],['ASCII']
+10.26302/sshade/bandlist_raman_huntite,Raman bandlist of Huntite,SSHADE/BANDLIST (OSUG Data Center),2023.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",MIR-FIR Raman bandlist of natural Huntite at 295K,mds,True,findable,0.0,0.0,2.0,0.0,0.0,2023-12-25T18:25:48.000Z,2023-12-25T18:25:49.000Z,inist.sshade,mgeg,"Huntite,Calcium cation,Magnesium(II) cation,Carbonate anion,Calcium(2+) cation,Magnesium(2+) cation,14127-61-8,22537-22-0,Ca2+,Mg2+,(CO3)2-,CaMg3(CO3)4,Huntite,non-silicate mineral,carbonate,carbonates, nitrates, borates,anhydrous carbonates,-Huntite- group,14.04.03.01,05.AB.25,Raman scattering,MIR,FIR,band frequency,band width,band intensity,transition and vibration modes","[{'subject': 'Huntite', 'subjectScheme': 'name'}, {'subject': 'Calcium cation', 'subjectScheme': 'name'}, {'subject': 'Magnesium(II) cation', 'subjectScheme': 'name'}, {'subject': 'Carbonate anion', 'subjectScheme': 'name'}, {'subject': 'Calcium(2+) cation', 'subjectScheme': 'IUPAC name'}, {'subject': 'Magnesium(2+) cation', 'subjectScheme': 'IUPAC name'}, {'subject': '14127-61-8', 'subjectScheme': 'CAS number'}, {'subject': '22537-22-0', 'subjectScheme': 'CAS number'}, {'subject': 'Ca2+', 'subjectScheme': 'formula'}, {'subject': 'Mg2+', 'subjectScheme': 'formula'}, {'subject': '(CO3)2-', 'subjectScheme': 'formula'}, {'subject': 'CaMg3(CO3)4', 'subjectScheme': 'formula'}, {'subject': 'Huntite', 'subjectScheme': 'IMA name'}, {'subject': 'non-silicate mineral', 'subjectScheme': 'mineral class'}, {'subject': 'carbonate', 'subjectScheme': 'compound type'}, {'subject': 'carbonates, nitrates, borates', 'subjectScheme': 'Dana class'}, {'subject': 'anhydrous carbonates', 'subjectScheme': 'Dana class'}, {'subject': '-Huntite- group', 'subjectScheme': 'Dana group'}, {'subject': '14.04.03.01', 'subjectScheme': 'Dana code'}, {'subject': '05.AB.25', 'subjectScheme': 'Strunz code'}, {'subject': 'Raman scattering', 'subjectScheme': 'variables'}, {'subject': 'MIR', 'subjectScheme': 'variables'}, {'subject': 'FIR', 'subjectScheme': 'variables'}, {'subject': 'band frequency', 'subjectScheme': 'variables'}, {'subject': 'band width', 'subjectScheme': 'variables'}, {'subject': 'band intensity', 'subjectScheme': 'variables'}, {'subject': 'transition and vibration modes', 'subjectScheme': 'variables'}]",,['ASCII']
+10.26302/sshade/experiment_ak_20141105_1,Mid-infrared attenuated total reflectance experiment with Na+ exchanged less 1 μm size fraction of beidellite (SbCa-1) equilibrated with D2O vapor under variable relative humidity,SSHADE/LSD (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2019-12-09T05:11:13.000Z,2019-12-09T05:11:14.000Z,inist.sshade,mgeg,"natural terrestrial,phyllosilicate,Na-exchanged beidellite SbCa-1 size-fraction <1 µm,liquid,D2O 99.9 Sigma-Aldrich,laboratory measurement,ATReflection,macroscopic,MIR,Mid-Infrared,corrected ATR absorbance","[{'subject': 'natural terrestrial'}, {'subject': 'phyllosilicate'}, {'subject': 'Na-exchanged beidellite SbCa-1 size-fraction <1 µm'}, {'subject': 'liquid'}, {'subject': 'D2O 99.9 Sigma-Aldrich'}, {'subject': 'laboratory measurement'}, {'subject': 'ATReflection'}, {'subject': 'macroscopic'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'corrected ATR absorbance'}]",['4 spectra'],['ASCII']
+10.26302/sshade/experiment_lb_20180718_001,MIR spectra of IOM from CM and C2-ungrouped chondrites under vacuum and at T=80C,SSHADE/GhoSST (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","MIR spectra of IOM extracted from a series of 20 CM and C2-ungrouped chondrites with the CF/HCl technique at IPAG and DTM, under vacuum and at low temperature",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2021-05-02T05:49:47.000Z,2021-05-02T05:49:48.000Z,inist.sshade,mgeg,"extraterrestrial,organic molecular solid,IOM CsF/HCl of BELLS,IOM CsF/HCl of ALH83100,IOM CsF/HCl of DOM03183,IOM CsF/HCl of EET87522,IOM CsF/HCl of ESSEBI,IOM CsF/HCl of MET01070,IOM CsF/HCl of Mighei,IOM CsF/HCl of Murray,IOM CsF/HCl of QUE97990,IOM CsF/HCl of LEW85311,IOM CsF/HCl (IPAG) of ALH84033,IOM CsF/HCl of ALH84044,IOM CsF/HCl (IPAG) of EET96029,IOM CsF/HCl of EET83355,IOM CsF/HCl (IPAG) of LEW85312,IOM CsF/HCl (IPAG) of LEW87022,IOM CsF/HCl (IPAG) of MAC88100,IOM CsF/HCl (IPAG) of MCY05230,IOM CsF/HCl (IPAG) of MET01072,IOM CsF/HCl (IPAG) of MIL07700,laboratory measurement,transmission,microscopy,MIR,Mid-Infrared,absorbance","[{'subject': 'extraterrestrial'}, {'subject': 'organic molecular solid'}, {'subject': 'IOM CsF/HCl of BELLS'}, {'subject': 'IOM CsF/HCl of ALH83100'}, {'subject': 'IOM CsF/HCl of DOM03183'}, {'subject': 'IOM CsF/HCl of EET87522'}, {'subject': 'IOM CsF/HCl of ESSEBI'}, {'subject': 'IOM CsF/HCl of MET01070'}, {'subject': 'IOM CsF/HCl of Mighei'}, {'subject': 'IOM CsF/HCl of Murray'}, {'subject': 'IOM CsF/HCl of QUE97990'}, {'subject': 'IOM CsF/HCl of LEW85311'}, {'subject': 'IOM CsF/HCl (IPAG) of ALH84033'}, {'subject': 'IOM CsF/HCl of ALH84044'}, {'subject': 'IOM CsF/HCl (IPAG) of EET96029'}, {'subject': 'IOM CsF/HCl of EET83355'}, {'subject': 'IOM CsF/HCl (IPAG) of LEW85312'}, {'subject': 'IOM CsF/HCl (IPAG) of LEW87022'}, {'subject': 'IOM CsF/HCl (IPAG) of MAC88100'}, {'subject': 'IOM CsF/HCl (IPAG) of MCY05230'}, {'subject': 'IOM CsF/HCl (IPAG) of MET01072'}, {'subject': 'IOM CsF/HCl (IPAG) of MIL07700'}, {'subject': 'laboratory measurement'}, {'subject': 'transmission'}, {'subject': 'microscopy'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'absorbance'}]",['20 spectra'],['ASCII']
+10.26302/sshade/experiment_ml_20171219_001,Zr K edge XAS fluorescence of natural vlasovite Na2ZrSi4O11 at ambient conditions,SSHADE/FAME (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2019-12-05T14:34:07.000Z,2019-12-05T14:34:10.000Z,inist.sshade,mgeg,"solid,commercial,non-oxide ceramic,BN powder,natural terrestrial,inosilicate,Natural vlasovite Na2ZrSi4O11,laboratory measurement,fluorescence emission,None,hard X","[{'subject': 'solid'}, {'subject': 'commercial'}, {'subject': 'non-oxide ceramic'}, {'subject': 'BN powder'}, {'subject': 'natural terrestrial'}, {'subject': 'inosilicate'}, {'subject': 'Natural vlasovite Na2ZrSi4O11'}, {'subject': 'laboratory measurement'}, {'subject': 'fluorescence emission'}, {'subject': 'None'}, {'subject': 'hard X'}]",['1 spectrum'],['ASCII']
+10.26302/sshade/experiment_kd_20170823,"Mass absorption coefficient spectra (cm2/g) of amorphous silicate Mg(1-x)Fe(x).SiO3, x=0.1, 0.2, 0.3 and 0.4, processed samples, at 10 to 300 K in the 5 - 1000 µm range",SSHADE/STOPCODA (OSUG Data Center),2019.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","Mass absorption coefficient spectra (cm2/g) of amorphous silicate $Mg_{(1-x)}Fe_x.SiO_3$, x=0.1, 0.2, 0.3 and 0.4, processed samples, at 10 to 300 K in the 5 - 1000 µm range (MIR to sub-mm)",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2019-11-01T08:26:54.000Z,2019-11-01T08:26:54.000Z,inist.sshade,mgeg,"solid,laboratory,non-oxide ceramic,Amorphous silicate Mg$_{(1-x)}$Fe$_x$SiO$_3$, x=0.1,commercial,homopolymer,Polyethylene HDPE,bromide,Potassium bromide KBr,Amorphous silicate Mg$_{(1-x)}$Fe$_x$SiO$_3$, x=0.2,Amorphous silicate Mg$_{(1-x)}$Fe$_x$SiO$_3$, x=0.3,Amorphous silicate Mg$_{(1-x)}$Fe$_x$SiO$_3$, x=0.4,laboratory measurement,transmission,macroscopic,MIR,Mid-Infrared,FIR,Far-Infrared,sub-mm,Sub-millimeter,absorption coefficient","[{'subject': 'solid'}, {'subject': 'laboratory'}, {'subject': 'non-oxide ceramic'}, {'subject': 'Amorphous silicate Mg$_{(1-x)}$Fe$_x$SiO$_3$, x=0.1'}, {'subject': 'commercial'}, {'subject': 'homopolymer'}, {'subject': 'Polyethylene HDPE'}, {'subject': 'bromide'}, {'subject': 'Potassium bromide KBr'}, {'subject': 'Amorphous silicate Mg$_{(1-x)}$Fe$_x$SiO$_3$, x=0.2'}, {'subject': 'Amorphous silicate Mg$_{(1-x)}$Fe$_x$SiO$_3$, x=0.3'}, {'subject': 'Amorphous silicate Mg$_{(1-x)}$Fe$_x$SiO$_3$, x=0.4'}, {'subject': 'laboratory measurement'}, {'subject': 'transmission'}, {'subject': 'macroscopic'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'FIR'}, {'subject': 'Far-Infrared'}, {'subject': 'sub-mm'}, {'subject': 'Sub-millimeter'}, {'subject': 'absorption coefficient'}]",['20 spectra'],['ASCII']
+10.26302/sshade/experiment_gv_20160403_001,Ni K edge XAS fluorescence of square planar Nickel(II) with Ni-N2S2 or Ni-S4 coordination at 16K,SSHADE/FAME (OSUG Data Center),2019.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2019-11-19T12:34:20.000Z,2019-11-19T12:34:20.000Z,inist.sshade,mgeg,"laboratory,molecular solid solution,Frozen solution of N,N’-dimethyl-N,N’-bis(2-mercaptoethyl)-1,3-propanediamine Nickel(II),Frozen solution of 1,2-bis(4-mercapto-3,3-dimethyl-2-thiabutyl)-benzene nickel(II),laboratory measurement,fluorescence emission,None,hard X,hard X-rays","[{'subject': 'laboratory'}, {'subject': 'molecular solid solution'}, {'subject': 'Frozen solution of N,N’-dimethyl-N,N’-bis(2-mercaptoethyl)-1,3-propanediamine Nickel(II)'}, {'subject': 'Frozen solution of 1,2-bis(4-mercapto-3,3-dimethyl-2-thiabutyl)-benzene nickel(II)'}, {'subject': 'laboratory measurement'}, {'subject': 'fluorescence emission'}, {'subject': 'None'}, {'subject': 'hard X'}, {'subject': 'hard X-rays'}]",['2 spectra'],['ASCII']
+10.5281/zenodo.10485575,"Fig. 1 in The chloroplast membrane associated ceQORH putative quinone oxidoreductase reduces long-chain, stress-related oxidized lipids",Zenodo,2016.0,,Image,License Not Specified,"Fig. 1. Detoxification of reactive Oi,β-unsaturated carbonyl compounds.",api,True,findable,0.0,0.0,0.0,0.0,0.0,2024-01-11T04:59:31.000Z,2024-01-11T04:59:31.000Z,cern.zenodo,cern,"Biodiversity,Taxonomy","[{'subject': 'Biodiversity'}, {'subject': 'Taxonomy'}]",,
+10.6084/m9.figshare.21430977,Additional file 3 of Digitally-supported patient-centered asynchronous outpatient follow-up in rheumatoid arthritis - an explorative qualitative study,figshare,2022.0,,Text,Creative Commons Attribution 4.0 International,Supplementary Material 3,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2022-10-29T03:17:16.000Z,2022-10-29T03:17:16.000Z,figshare.ars,otjm,"Medicine,Immunology,FOS: Clinical medicine,69999 Biological Sciences not elsewhere classified,FOS: Biological sciences,Science Policy,111714 Mental Health,FOS: Health sciences","[{'subject': 'Medicine'}, {'subject': 'Immunology'}, {'subject': 'FOS: Clinical medicine', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': '69999 Biological Sciences not elsewhere classified', 'schemeUri': 'http://www.abs.gov.au/ausstats/abs@.nsf/0/6BB427AB9696C225CA2574180004463E', 'subjectScheme': 'FOR'}, {'subject': 'FOS: Biological sciences', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': 'Science Policy'}, {'subject': '111714 Mental Health', 'schemeUri': 'http://www.abs.gov.au/ausstats/abs@.nsf/0/6BB427AB9696C225CA2574180004463E', 'subjectScheme': 'FOR'}, {'subject': 'FOS: Health sciences', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}]",['493283 Bytes'],
+10.15778/resif.zh2003,Seismic network ZH:NORTH ZAGROS lithospheric transect (RESIF-SISMOB),RESIF - Réseau Sismologique et géodésique Français,2006.0,en,Other,"Open Access,Creative Commons Attribution 4.0 International","Temporary seismic network across Northern Zagros (Iran). Goal: seismic imaging of the lithosphere from earthquake data. 42 stations on a 470-km long profile. Sensors: Güralp CMG40-T and CMG3-ESP, Streckheisen STS-2, Lennartz Le-3D-5s. Digitizers: Agecodagis Minititan.",mds,True,findable,0.0,0.0,0.0,1.0,0.0,2014-12-09T06:25:54.000Z,2014-12-09T06:25:54.000Z,inist.resif,vcob,"Zagros,Lithospheric structure","[{'subject': 'Zagros'}, {'subject': 'Lithospheric structure'}]",,
+10.26302/sshade/experiment_ml_20171220_002,Zr K edge XAS fluorescence of haplogranite Zr glass at ambient conditions,SSHADE/FAME (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2019-12-05T14:07:20.000Z,2019-12-05T14:07:21.000Z,inist.sshade,mgeg,"laboratory,silicate,Haplogranite Zr glass,laboratory measurement,fluorescence emission,None,hard X","[{'subject': 'laboratory'}, {'subject': 'silicate'}, {'subject': 'Haplogranite Zr glass'}, {'subject': 'laboratory measurement'}, {'subject': 'fluorescence emission'}, {'subject': 'None'}, {'subject': 'hard X'}]",['1 spectrum'],['ASCII']
+10.26302/sshade/experiment_ml_20171219_004,Zr K edge XAS fluorescence of synthetic baddeleyite ZrO2 at ambient conditions,SSHADE/FAME (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2019-12-05T13:56:56.000Z,2019-12-05T13:56:57.000Z,inist.sshade,mgeg,"solid,commercial,non-oxide ceramic,BN powder,laboratory,oxide-hydroxide,Synthetic baddeleyite,laboratory measurement,fluorescence emission,None,hard X","[{'subject': 'solid'}, {'subject': 'commercial'}, {'subject': 'non-oxide ceramic'}, {'subject': 'BN powder'}, {'subject': 'laboratory'}, {'subject': 'oxide-hydroxide'}, {'subject': 'Synthetic baddeleyite'}, {'subject': 'laboratory measurement'}, {'subject': 'fluorescence emission'}, {'subject': 'None'}, {'subject': 'hard X'}]",['1 spectrum'],['ASCII']
+10.26302/sshade/experiment_gl_20150101_1,Mid-infrared diffuse reflectance experiment with chlorite (Mg-chamosite) heated in-situ from 25 to 800°C,SSHADE/LSD (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2022-11-04T08:24:14.000Z,2022-11-04T08:24:14.000Z,inist.sshade,mgeg,"mineral,natural terrestrial,phyllosilicate,chamosite,commercial,elemental solid,Synthetic diamond powder,laboratory measurement,diffuse reflection,macroscopic,MIR,Mid-Infrared,absorbance","[{'subject': 'mineral'}, {'subject': 'natural terrestrial'}, {'subject': 'phyllosilicate'}, {'subject': 'chamosite'}, {'subject': 'commercial'}, {'subject': 'elemental solid'}, {'subject': 'Synthetic diamond powder'}, {'subject': 'laboratory measurement'}, {'subject': 'diffuse reflection'}, {'subject': 'macroscopic'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'absorbance'}]",['4 spectra'],['ASCII']
+10.26302/sshade/experiment_cl_20181202_03,Ion irradiation ($He^+$) of a Mighei meteorite pellet probed by NIR spectroscopy,SSHADE/DAYSY (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","NIR spectra of Mighei meteorite pellet, before and after ion irradiation at different doses.",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2022-05-27T17:02:18.000Z,2022-05-27T17:02:19.000Z,inist.sshade,mgeg,"extraterrestrial,carbonaceous chondrite,CM,complex organic-mineral mix,matrix Mighei,complex mineral mix,chondrules Mighei,CAIs Mighei,laboratory measurement,bidirectional reflection,macroscopic,NIR,Near-Infrared,reflectance factor","[{'subject': 'extraterrestrial'}, {'subject': 'carbonaceous chondrite'}, {'subject': 'CM'}, {'subject': 'complex organic-mineral mix'}, {'subject': 'matrix Mighei'}, {'subject': 'complex mineral mix'}, {'subject': 'chondrules Mighei'}, {'subject': 'CAIs Mighei'}, {'subject': 'laboratory measurement'}, {'subject': 'bidirectional reflection'}, {'subject': 'macroscopic'}, {'subject': 'NIR'}, {'subject': 'Near-Infrared'}, {'subject': 'reflectance factor'}]",['5 spectra'],['ASCII']
+10.26302/sshade/experiment_bs_20201114_014,"Near-infrared reflectance spectra at low temperature (300-90K) of Ammonium bicarbonate [(NH4)HCO3] powders with three grain size ranges (32-80, 80-125 and 125-150µm)",SSHADE/CSS (OSUG Data Center),2022.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",Near-infrared reflectance spectra at low temperature (290-90K) of Ammonium bicarbonate powder [(NH4)HCO3] with 32-80 µm grain size and at room temperature (300K) with 80-125µm and 125-150µm grain sizes,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2022-04-23T08:15:10.000Z,2022-04-23T08:15:10.000Z,inist.sshade,mgeg,"commercial,carbonate,Ammonium bicarbonate,laboratory measurement,bidirectional reflection,macroscopic,NIR,Near-Infrared,reflectance factor","[{'subject': 'commercial'}, {'subject': 'carbonate'}, {'subject': 'Ammonium bicarbonate'}, {'subject': 'laboratory measurement'}, {'subject': 'bidirectional reflection'}, {'subject': 'macroscopic'}, {'subject': 'NIR'}, {'subject': 'Near-Infrared'}, {'subject': 'reflectance factor'}]",['17 spectra'],['ASCII']
+10.6084/m9.figshare.22625623,"Additional file 6 of A multicentre, patient- and assessor-blinded, non-inferiority, randomised and controlled phase II trial to compare standard and torque teno virus-guided immunosuppression in kidney transplant recipients in the first year after transplantation: TTVguideIT",figshare,2023.0,,Text,Creative Commons Attribution 4.0 International,Additional file 6.,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-04-13T18:56:19.000Z,2023-04-13T18:56:20.000Z,figshare.ars,otjm,"Immunology,FOS: Clinical medicine","[{'subject': 'Immunology'}, {'subject': 'FOS: Clinical medicine', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}]",['190912 Bytes'],
+10.26302/sshade/experiment_bs_20181101_001,"Vis-NIR reflectance spectra of a mix of three PAHs, PAHs mixed with CO2 snow and PAHs mixed with JSC Mars-1 simulant",SSHADE/CSS (OSUG Data Center),2021.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","Vis-NIR reflectance spectra of a series of samples with a mix of 3 PAHs (Anthracene, Phenanthrene-d10 and Pyrene), JSC Mars-1 dust, PAHs mixed with CO2 snow with different abundances (0.1%, 0.54%, 0.67%) and 1.5% PAHs mixed with JSC Mars-1 dust",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2021-05-25T12:01:03.000Z,2021-05-25T12:01:04.000Z,inist.sshade,mgeg,"solid,commercial,organic molecular solid,Anthracene,Phenanthrene-d10,Pyrene,laboratory,inorganic molecular solid,solid CO2,H2O ice,natural terrestrial,oxide-hydroxide,Magnetite,Ulvospinel,tektosilicate,Anorthite,nesosilicate,Olivine,Ferrihydrite,inosilicate,Augite,Orthopyroxenes,laboratory measurement,bidirectional reflection,macroscopic,Vis,Visible,NIR,Near-Infrared,reflectance factor","[{'subject': 'solid'}, {'subject': 'commercial'}, {'subject': 'organic molecular solid'}, {'subject': 'Anthracene'}, {'subject': 'Phenanthrene-d10'}, {'subject': 'Pyrene'}, {'subject': 'laboratory'}, {'subject': 'inorganic molecular solid'}, {'subject': 'solid CO2'}, {'subject': 'H2O ice'}, {'subject': 'natural terrestrial'}, {'subject': 'oxide-hydroxide'}, {'subject': 'Magnetite'}, {'subject': 'Ulvospinel'}, {'subject': 'tektosilicate'}, {'subject': 'Anorthite'}, {'subject': 'nesosilicate'}, {'subject': 'Olivine'}, {'subject': 'Ferrihydrite'}, {'subject': 'inosilicate'}, {'subject': 'Augite'}, {'subject': 'Orthopyroxenes'}, {'subject': 'laboratory measurement'}, {'subject': 'bidirectional reflection'}, {'subject': 'macroscopic'}, {'subject': 'Vis'}, {'subject': 'Visible'}, {'subject': 'NIR'}, {'subject': 'Near-Infrared'}, {'subject': 'reflectance factor'}]",['21 spectra'],['ASCII']
+10.26302/sshade/experiment_gm_20220331,Raman spectra of some SiO2 polymorphs,SSHADE/REAP (OSUG Data Center),2022.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2022-04-08T09:29:27.000Z,2022-04-08T09:29:28.000Z,inist.sshade,mgeg,"commercial,tektosilicate,Quartz alpha,natural terrestrial,Coesite,Cristobalite,oxide-hydroxide,Stishovite,tridymite,laboratory measurement,Raman scattering,microscopy,MIR,Mid-Infrared,FIR,Far-Infrared,normalized Raman scattering intensity","[{'subject': 'commercial'}, {'subject': 'tektosilicate'}, {'subject': 'Quartz alpha'}, {'subject': 'natural terrestrial'}, {'subject': 'Coesite'}, {'subject': 'Cristobalite'}, {'subject': 'oxide-hydroxide'}, {'subject': 'Stishovite'}, {'subject': 'tridymite'}, {'subject': 'laboratory measurement'}, {'subject': 'Raman scattering'}, {'subject': 'microscopy'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'FIR'}, {'subject': 'Far-Infrared'}, {'subject': 'normalized Raman scattering intensity'}]",['5 spectra'],['ASCII']
+10.6084/m9.figshare.23575372,Additional file 5 of Decoupling of arsenic and iron release from ferrihydrite suspension under reducing conditions: a biogeochemical model,figshare,2023.0,,Text,Creative Commons Attribution 4.0 International,Authors’ original file for figure 4,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-06-25T03:11:51.000Z,2023-06-25T03:11:51.000Z,figshare.ars,otjm,"59999 Environmental Sciences not elsewhere classified,FOS: Earth and related environmental sciences,39999 Chemical Sciences not elsewhere classified,FOS: Chemical sciences,Ecology,FOS: Biological sciences,69999 Biological Sciences not elsewhere classified,Cancer","[{'subject': '59999 Environmental Sciences not elsewhere classified', 'schemeUri': 'http://www.abs.gov.au/ausstats/abs@.nsf/0/6BB427AB9696C225CA2574180004463E', 'subjectScheme': 'FOR'}, {'subject': 'FOS: Earth and related environmental sciences', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': '39999 Chemical Sciences not elsewhere classified', 'schemeUri': 'http://www.abs.gov.au/ausstats/abs@.nsf/0/6BB427AB9696C225CA2574180004463E', 'subjectScheme': 'FOR'}, {'subject': 'FOS: Chemical sciences', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': 'Ecology'}, {'subject': 'FOS: Biological sciences', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': '69999 Biological Sciences not elsewhere classified', 'schemeUri': 'http://www.abs.gov.au/ausstats/abs@.nsf/0/6BB427AB9696C225CA2574180004463E', 'subjectScheme': 'FOR'}, {'subject': 'Cancer'}]",['24064 Bytes'],
+10.26302/sshade/experiment_bs_20191214_001,"Vis-NIR spectra of NH4-Montmorillonite, Antigorite, Dolomite and Graphite and their mixtures with different grain sizes and temperatures (140-300 K)",SSHADE/CSS+REFL_SLAB (OSUG Data Center),2020.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","Vis-NIR spectra of NH4-Montmorillonite (0-25µm / 180-290K; 25-50µm / 200K), Antigorite (25-50µm / 200K; 50-100µm / 180-290K), Dolomite (0-25µm / 140-200K; 50-100µm / 200K), and Graphite (>100µm / 290K) and 5 mixtures: #1: Mo6%:An5%:Do5%:Gr84% (0-25µm / 290K); #2: Mo17%:An24%:Do57%:Gr2% (50-100µm / 290K); #3a: Mo9%:An19%:Do64%:Gr8% (50-100µm / 290K); #3b: Mo9%:An19%:Do60%:Gr12% (50-100µm / 290K); #4: Mo28%:An36%:Do18%:Gr18% (0-25, 25-50, 50-100µm / 200, 300K)",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2020-03-02T12:02:28.000Z,2020-03-02T12:02:29.000Z,inist.sshade,mgeg,"mineral,natural terrestrial,laboratory,phyllosilicate,NH4-montmorillonite,interlayer phase,interlayer water,Antigorite,carbonate,Dolomite,commercial,elemental solid,Graphite,Mg-Carbonate,laboratory measurement,bidirectional reflection,macroscopic,Vis,Visible,NIR,Near-Infrared,reflectance factor","[{'subject': 'mineral'}, {'subject': 'natural terrestrial'}, {'subject': 'laboratory'}, {'subject': 'phyllosilicate'}, {'subject': 'NH4-montmorillonite'}, {'subject': 'interlayer phase'}, {'subject': 'interlayer water'}, {'subject': 'Antigorite'}, {'subject': 'carbonate'}, {'subject': 'Dolomite'}, {'subject': 'commercial'}, {'subject': 'elemental solid'}, {'subject': 'Graphite'}, {'subject': 'Mg-Carbonate'}, {'subject': 'laboratory measurement'}, {'subject': 'bidirectional reflection'}, {'subject': 'macroscopic'}, {'subject': 'Vis'}, {'subject': 'Visible'}, {'subject': 'NIR'}, {'subject': 'Near-Infrared'}, {'subject': 'reflectance factor'}]",['42 spectra'],['ASCII']
+10.26302/sshade/experiment_bs_20201121_013,"Near-infrared reflectance spectra at low temperature (300-80K) of Mascagnite and FE-Ammmonium sulfate [(NH4)2SO4] powders with three grain size ranges (32-80, 80-125 and 125-150µm)",SSHADE/CSS (OSUG Data Center),2022.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",Near-infrared reflectance spectra at low temperature of Mascagnite (290-223K) and FE-Ammmonium sulfate (222-80K) [(NH4)2SO4] powder with 32-80 µm grain size and Mascagnite at room temperature with 80-125µm and 125-150µm grain sizes,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2022-04-23T08:17:08.000Z,2022-04-23T08:17:09.000Z,inist.sshade,mgeg,"natural terrestrial,sulfate,Mascagnite,Ammmonium sulfate (phase FE),laboratory measurement,bidirectional reflection,macroscopic,NIR,Near-Infrared,reflectance factor","[{'subject': 'natural terrestrial'}, {'subject': 'sulfate'}, {'subject': 'Mascagnite'}, {'subject': 'Ammmonium sulfate (phase FE)'}, {'subject': 'laboratory measurement'}, {'subject': 'bidirectional reflection'}, {'subject': 'macroscopic'}, {'subject': 'NIR'}, {'subject': 'Near-Infrared'}, {'subject': 'reflectance factor'}]",['38 spectra'],['ASCII']
+10.26302/sshade/experiment_gp_20180208_001,Pt L3 edge XAS fluorescence and XAS transmission of Aqueous platinum chloride soutions at 600-700 nars and 30°C,SSHADE/FAME (OSUG Data Center),2022.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","Platinum (IV) and platinum (II) chloride aqueous solutions references at concentration around 0.1m Pt, in transmission and in fluorescence.",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2022-12-13T11:19:21.000Z,2022-12-13T11:19:21.000Z,inist.sshade,mgeg,"laboratory,liquid solution,K2PtCl4 aq solution 0.0148m + 0.233m HCl + 0.004m KBr,H2PtCl6 aq solution 0.007m + 0.616m HCl + 0.004m KBr,solid,commercial,non-oxide ceramic,BN powder,chloride,K2PtCl4,K2PtCl6,laboratory measurement,fluorescence emission,None,hard X,hard X-rays,transmission","[{'subject': 'laboratory'}, {'subject': 'liquid solution'}, {'subject': 'K2PtCl4 aq solution 0.0148m + 0.233m HCl + 0.004m KBr'}, {'subject': 'H2PtCl6 aq solution 0.007m + 0.616m HCl + 0.004m KBr'}, {'subject': 'solid'}, {'subject': 'commercial'}, {'subject': 'non-oxide ceramic'}, {'subject': 'BN powder'}, {'subject': 'chloride'}, {'subject': 'K2PtCl4'}, {'subject': 'K2PtCl6'}, {'subject': 'laboratory measurement'}, {'subject': 'fluorescence emission'}, {'subject': 'None'}, {'subject': 'hard X'}, {'subject': 'hard X-rays'}, {'subject': 'transmission'}]",['6 spectra'],['ASCII']
+10.6084/m9.figshare.21368764,Additional file 1 of Acute mesenteric ischemia: updated guidelines of the World Society of Emergency Surgery,figshare,2022.0,,Text,Creative Commons Attribution 4.0 International,Additional file 1: Table S3. Summary of the updated 2022 guidelines for AMI: statements and recommendations.,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2022-10-20T06:32:08.000Z,2022-10-20T06:32:09.000Z,figshare.ars,otjm,"Medicine,Genetics,FOS: Biological sciences,Neuroscience,Biotechnology,80699 Information Systems not elsewhere classified,FOS: Computer and information sciences","[{'subject': 'Medicine'}, {'subject': 'Genetics'}, {'subject': 'FOS: Biological sciences', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': 'Neuroscience'}, {'subject': 'Biotechnology'}, {'subject': '80699 Information Systems not elsewhere classified', 'schemeUri': 'http://www.abs.gov.au/ausstats/abs@.nsf/0/6BB427AB9696C225CA2574180004463E', 'subjectScheme': 'FOR'}, {'subject': 'FOS: Computer and information sciences', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}]",['26216 Bytes'],
+10.26302/sshade/experiment_zed_20230127_01,FIR spectra of carbonaceous chondrites pellets irradiated by $He^+$ ions,SSHADE/DAYSY (OSUG Data Center),2023.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",Far-IR spectra of carbonaceous chondrite pellets: unirradiated area and area irradiated by $He^+$ ions at 40 keV and a total fluence of $6.10^{16} ions.cm{-2}$.,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-05-25T13:55:43.000Z,2023-05-25T13:55:44.000Z,inist.sshade,mgeg,"laboratory measurement,confocal reflection,micro-imaging,FIR,Far-Infrared,normalized reflectance,matrix Alais,chondrules Alais,CAIs Alais,matrix TagishLake,chondrules TagishLake,CAIs Tagish Lake,matrix Mighei,chondrules Mighei,CAIs Mighei,matrix Allende,chondrules Allende,CAIs Allende,matrix Lancé,chondrules Lancé,CAIs Lancé,matrix FRO95002,chondrules FRO95002,CAIs FRO95002,extraterrestrial,complex organic-mineral mix,complex mineral mix,carbonaceous chondrite,CI,ungrouped,CM,CV,CO","[{'subject': 'laboratory measurement', 'subjectScheme': 'main'}, {'subject': 'confocal reflection', 'subjectScheme': 'main'}, {'subject': 'micro-imaging', 'subjectScheme': 'main'}, {'subject': 'FIR', 'subjectScheme': 'variables'}, {'subject': 'Far-Infrared', 'subjectScheme': 'variables'}, {'subject': 'normalized reflectance', 'subjectScheme': 'variables'}, {'subject': 'matrix Alais', 'subjectScheme': 'name'}, {'subject': 'chondrules Alais', 'subjectScheme': 'name'}, {'subject': 'CAIs Alais', 'subjectScheme': 'name'}, {'subject': 'matrix TagishLake', 'subjectScheme': 'name'}, {'subject': 'chondrules TagishLake', 'subjectScheme': 'name'}, {'subject': 'CAIs Tagish Lake', 'subjectScheme': 'name'}, {'subject': 'matrix Mighei', 'subjectScheme': 'name'}, {'subject': 'chondrules Mighei', 'subjectScheme': 'name'}, {'subject': 'CAIs Mighei', 'subjectScheme': 'name'}, {'subject': 'matrix Allende', 'subjectScheme': 'name'}, {'subject': 'chondrules Allende', 'subjectScheme': 'name'}, {'subject': 'CAIs Allende', 'subjectScheme': 'name'}, {'subject': 'matrix Lancé', 'subjectScheme': 'name'}, {'subject': 'chondrules Lancé', 'subjectScheme': 'name'}, {'subject': 'CAIs Lancé', 'subjectScheme': 'name'}, {'subject': 'matrix FRO95002', 'subjectScheme': 'name'}, {'subject': 'chondrules FRO95002', 'subjectScheme': 'name'}, {'subject': 'CAIs FRO95002', 'subjectScheme': 'name'}, {'subject': 'extraterrestrial', 'subjectScheme': 'family'}, {'subject': 'complex organic-mineral mix', 'subjectScheme': 'compound type'}, {'subject': 'complex mineral mix', 'subjectScheme': 'compound type'}, {'subject': 'carbonaceous chondrite', 'subjectScheme': 'meteorite group'}, {'subject': 'CI', 'subjectScheme': 'meteorite class'}, {'subject': 'ungrouped', 'subjectScheme': 'meteorite class'}, {'subject': 'CM', 'subjectScheme': 'meteorite class'}, {'subject': 'CV', 'subjectScheme': 'meteorite class'}, {'subject': 'CO', 'subjectScheme': 'meteorite class'}]",['12 spectra'],['ASCII']
+10.26302/sshade/experiment_op_20230203_001,NIR-MIR reflectance spectra of powdered Olivine at 4 different grain sizes (from 200 µm down to sub-µm),SSHADE/GhoSST (OSUG Data Center),2023.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","We measured the reflectance spectra (from 1 to 25 µm) of powders of olivine. The powders were grinded and sieved and the spectra of four size fractions were measured: 100-200 µm, 50-100 µm, 25-50 µm, and sub-micrometer sized grains.",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-02-06T14:19:15.000Z,2023-02-06T14:19:16.000Z,inist.sshade,mgeg,"mineral,laboratory,natural terrestrial,nesosilicate,Olivine Forsterite,tektosilicate,Quartz,laboratory measurement,transmission,macroscopic,NIR,Near-Infrared,MIR,Mid-Infrared,bidirectional reflection,Vis,Visible,reflectance factor","[{'subject': 'mineral'}, {'subject': 'laboratory'}, {'subject': 'natural terrestrial'}, {'subject': 'nesosilicate'}, {'subject': 'Olivine Forsterite'}, {'subject': 'tektosilicate'}, {'subject': 'Quartz'}, {'subject': 'laboratory measurement'}, {'subject': 'transmission'}, {'subject': 'macroscopic'}, {'subject': 'NIR'}, {'subject': 'Near-Infrared'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'bidirectional reflection'}, {'subject': 'Vis'}, {'subject': 'Visible'}, {'subject': 'reflectance factor'}]",['4 spectra'],['ASCII']
+10.26302/sshade/experiment_lb_20191220_004,"NIR reflectance spectrum (i=0°, e=30°) of bulk UOC chondrites under vacuum at T = 80°C",SSHADE/GhoSST (OSUG Data Center),2022.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","NIR reflectance spectra (i = 0°, e=30°) of bulk UOC chondrites under vacuum at T = 80°C",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2020-08-13T09:15:25.000Z,2020-08-13T09:15:29.000Z,inist.sshade,mgeg,"extraterrestrial,ordinary chondrite,H,complex organic-mineral mix,matrix BTN00302,complex mineral mix,chondrules BTN00302,CAIs BTN00302,matrix EET83248,chondrules EET83248,CAIs EET83248,matrix RBT04251,chondrules RBT04251,CAIs RBT04251,matrix MCY05218,chondrules MCY05218,CAIs MCY05218,matrix WIS91627,chondrules WIS91627,CAIs WIS91627,matrix DOM08468,chondrules DOM08468,CAIs DOM08468,matrix LAR04382,chondrules LAR04382,CAIs LAR04382,matrix MAC88174,chondrules MAC88174,CAIs MAC88174,matrix MET00506,chondrules MET00506,CAIs MET00506,matrix WSG95300,chondrules WSG95300,CAIs WSG95300,L,matrix EET90066,chondrules EET90066,CAIs EET90066,matrix EET90628,chondrules EET90628,CAIs EET90628,matrix GRO06054,chondrules GRO06054,CAIs GRO06054,matrix LEW87248,chondrules LEW87248,CAIs LEW87248,matrix MET00489,chondrules MET00489,CAIs MET00489,matrix LEW87284,chondrules LEW87284,CAIs LEW87284,matrix ALH83008,chondrules ALH83008,CAIs ALH83008,matrix ALH84086,chondrules ALH84086,CAIs ALH84086,matrix ALH84120,chondrules ALH84120,CAIs ALH84120,matrix DOM03287,chondrules DOM03287,CAIs DOM03287,matrix EET87735,chondrules EET87735,CAIs EET87735,matrix LEW88617,chondrules LEW88617,CAIs LEW88617,matrix LEW88632,chondrules LEW88632,CAIs LEW88632,matrix MIL05050,chondrules MIL05050,CAIs MIL05050,matrix MIL05076,chondrules MIL05076,CAIs MIL05076,LL,matrix ALHA76004,chondrules ALHA76004,CAIs ALHA76004,matrix TIL82408,chondrules TIL82408,CAIs TIL82408,matrix EET96188,chondrules EET96188,CAIs EET96188,matrix LAR06279,chondrules LAR06279,CAIs LAR06279,matrix ALHA78119,chondrules ALHA78119,CAIs ALHA78119,matrix LAR06469,chondrules LAR06469,CAIs LAR06469,matrix Bishunpur,chondrules Bishunpur,CAIs Bishunpur,H/L,matrix Bremervorde,chondrules Bremervorde,CAIs Bremervorde,matrix Chainpur,chondrules Chainpur,CAIs Chainpur,matrix Dhajala,chondrules Dhajala,CAIs Dhajala,matrix Hallingeberg,chondrules Hallingeberg,CAIs Hallingeberg,matrix Krymka,chondrules Krymka,CAIs Krymka,matrix Mezo-Madaras,chondrules Mezo-Madaras,CAIs Mezo-Madaras,matrix Parnallee,chondrules Parnallee,CAIs Parnallee,matrix Piancaldoli,chondrules Piancaldoli,CAIs Piancaldoli,matrix Tieschitz,chondrules Tieschitz,CAIs Tieschitz,laboratory measurement,bidirectional reflection,macroscopic,Vis,Visible,NIR,Near-Infrared,reflectance factor","[{'subject': 'extraterrestrial'}, {'subject': 'ordinary chondrite'}, {'subject': 'H'}, {'subject': 'complex organic-mineral mix'}, {'subject': 'matrix BTN00302'}, {'subject': 'complex mineral mix'}, {'subject': 'chondrules BTN00302'}, {'subject': 'CAIs BTN00302'}, {'subject': 'matrix EET83248'}, {'subject': 'chondrules EET83248'}, {'subject': 'CAIs EET83248'}, {'subject': 'matrix RBT04251'}, {'subject': 'chondrules RBT04251'}, {'subject': 'CAIs RBT04251'}, {'subject': 'matrix MCY05218'}, {'subject': 'chondrules MCY05218'}, {'subject': 'CAIs MCY05218'}, {'subject': 'matrix WIS91627'}, {'subject': 'chondrules WIS91627'}, {'subject': 'CAIs WIS91627'}, {'subject': 'matrix DOM08468'}, {'subject': 'chondrules DOM08468'}, {'subject': 'CAIs DOM08468'}, {'subject': 'matrix LAR04382'}, {'subject': 'chondrules LAR04382'}, {'subject': 'CAIs LAR04382'}, {'subject': 'matrix MAC88174'}, {'subject': 'chondrules MAC88174'}, {'subject': 'CAIs MAC88174'}, {'subject': 'matrix MET00506'}, {'subject': 'chondrules MET00506'}, {'subject': 'CAIs MET00506'}, {'subject': 'matrix WSG95300'}, {'subject': 'chondrules WSG95300'}, {'subject': 'CAIs WSG95300'}, {'subject': 'L'}, {'subject': 'matrix EET90066'}, {'subject': 'chondrules EET90066'}, {'subject': 'CAIs EET90066'}, {'subject': 'matrix EET90628'}, {'subject': 'chondrules EET90628'}, {'subject': 'CAIs EET90628'}, {'subject': 'matrix GRO06054'}, {'subject': 'chondrules GRO06054'}, {'subject': 'CAIs GRO06054'}, {'subject': 'matrix LEW87248'}, {'subject': 'chondrules LEW87248'}, {'subject': 'CAIs LEW87248'}, {'subject': 'matrix MET00489'}, {'subject': 'chondrules MET00489'}, {'subject': 'CAIs MET00489'}, {'subject': 'matrix LEW87284'}, {'subject': 'chondrules LEW87284'}, {'subject': 'CAIs LEW87284'}, {'subject': 'matrix ALH83008'}, {'subject': 'chondrules ALH83008'}, {'subject': 'CAIs ALH83008'}, {'subject': 'matrix ALH84086'}, {'subject': 'chondrules ALH84086'}, {'subject': 'CAIs ALH84086'}, {'subject': 'matrix ALH84120'}, {'subject': 'chondrules ALH84120'}, {'subject': 'CAIs ALH84120'}, {'subject': 'matrix DOM03287'}, {'subject': 'chondrules DOM03287'}, {'subject': 'CAIs DOM03287'}, {'subject': 'matrix EET87735'}, {'subject': 'chondrules EET87735'}, {'subject': 'CAIs EET87735'}, {'subject': 'matrix LEW88617'}, {'subject': 'chondrules LEW88617'}, {'subject': 'CAIs LEW88617'}, {'subject': 'matrix LEW88632'}, {'subject': 'chondrules LEW88632'}, {'subject': 'CAIs LEW88632'}, {'subject': 'matrix MIL05050'}, {'subject': 'chondrules MIL05050'}, {'subject': 'CAIs MIL05050'}, {'subject': 'matrix MIL05076'}, {'subject': 'chondrules MIL05076'}, {'subject': 'CAIs MIL05076'}, {'subject': 'LL'}, {'subject': 'matrix ALHA76004'}, {'subject': 'chondrules ALHA76004'}, {'subject': 'CAIs ALHA76004'}, {'subject': 'matrix TIL82408'}, {'subject': 'chondrules TIL82408'}, {'subject': 'CAIs TIL82408'}, {'subject': 'matrix EET96188'}, {'subject': 'chondrules EET96188'}, {'subject': 'CAIs EET96188'}, {'subject': 'matrix LAR06279'}, {'subject': 'chondrules LAR06279'}, {'subject': 'CAIs LAR06279'}, {'subject': 'matrix ALHA78119'}, {'subject': 'chondrules ALHA78119'}, {'subject': 'CAIs ALHA78119'}, {'subject': 'matrix LAR06469'}, {'subject': 'chondrules LAR06469'}, {'subject': 'CAIs LAR06469'}, {'subject': 'matrix Bishunpur'}, {'subject': 'chondrules Bishunpur'}, {'subject': 'CAIs Bishunpur'}, {'subject': 'H/L'}, {'subject': 'matrix Bremervorde'}, {'subject': 'chondrules Bremervorde'}, {'subject': 'CAIs Bremervorde'}, {'subject': 'matrix Chainpur'}, {'subject': 'chondrules Chainpur'}, {'subject': 'CAIs Chainpur'}, {'subject': 'matrix Dhajala'}, {'subject': 'chondrules Dhajala'}, {'subject': 'CAIs Dhajala'}, {'subject': 'matrix Hallingeberg'}, {'subject': 'chondrules Hallingeberg'}, {'subject': 'CAIs Hallingeberg'}, {'subject': 'matrix Krymka'}, {'subject': 'chondrules Krymka'}, {'subject': 'CAIs Krymka'}, {'subject': 'matrix Mezo-Madaras'}, {'subject': 'chondrules Mezo-Madaras'}, {'subject': 'CAIs Mezo-Madaras'}, {'subject': 'matrix Parnallee'}, {'subject': 'chondrules Parnallee'}, {'subject': 'CAIs Parnallee'}, {'subject': 'matrix Piancaldoli'}, {'subject': 'chondrules Piancaldoli'}, {'subject': 'CAIs Piancaldoli'}, {'subject': 'matrix Tieschitz'}, {'subject': 'chondrules Tieschitz'}, {'subject': 'CAIs Tieschitz'}, {'subject': 'laboratory measurement'}, {'subject': 'bidirectional reflection'}, {'subject': 'macroscopic'}, {'subject': 'Vis'}, {'subject': 'Visible'}, {'subject': 'NIR'}, {'subject': 'Near-Infrared'}, {'subject': 'reflectance factor'}]",['41 spectra'],['ASCII']
+10.26302/sshade/experiment_op_20230206_002,NIR-MIR absorbance spectrum of a pellet of Olivine (sub-µm grains) mixed with KBr,SSHADE/GhoSST (OSUG Data Center),2023.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",We measured the absorbance spectra (from 1 to 25 µm) of a pellet made of powders of olivine sub-µm grains and KBr.,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-02-07T08:23:44.000Z,2023-02-07T08:23:45.000Z,inist.sshade,mgeg,"mineral,laboratory,natural terrestrial,nesosilicate,Olivine Forsterite,tektosilicate,Quartz,solid,commercial,bromide,KBr,laboratory measurement,transmission,macroscopic,NIR,Near-Infrared,MIR,Mid-Infrared,absorbance","[{'subject': 'mineral'}, {'subject': 'laboratory'}, {'subject': 'natural terrestrial'}, {'subject': 'nesosilicate'}, {'subject': 'Olivine Forsterite'}, {'subject': 'tektosilicate'}, {'subject': 'Quartz'}, {'subject': 'solid'}, {'subject': 'commercial'}, {'subject': 'bromide'}, {'subject': 'KBr'}, {'subject': 'laboratory measurement'}, {'subject': 'transmission'}, {'subject': 'macroscopic'}, {'subject': 'NIR'}, {'subject': 'Near-Infrared'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'absorbance'}]",['1 spectrum'],['ASCII']
+10.5281/zenodo.10619442,"Data and Code for ""Energetically consistent Eddy-Diffusivity Mass-Flux schemes for Atmospheric and Oceanic Convection""",Zenodo,2024.0,,Software,Creative Commons Attribution 4.0 International,"This repository contains the codes and data used to produce the figures of ""Energetically consistent Eddy-Diffusivity Mass-Flux schemes for Atmospheric and Oceanic Convection"", a paper by M. Perrot and  F. Lemarié submitted to Journal of Advanced Modelling in Earth Sciences. See readme.md for pratical usage.",api,True,findable,0.0,0.0,0.0,0.0,0.0,2024-02-05T14:45:11.000Z,2024-02-05T14:45:12.000Z,cern.zenodo,cern,,,,
+10.26302/sshade/experiment_ak_20141101_1,Mid-infrared attenuated total reflectance experiment with Na+ exchanged less 1 μm size fraction of nontronite (SWa-1) equilibrated with D2O vapor under variable relative humidity,SSHADE/LSD (OSUG Data Center),2019.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2022-11-04T08:11:24.000Z,2022-11-04T08:11:25.000Z,inist.sshade,mgeg,"natural terrestrial,phyllosilicate,Na-exchanged smectite SWa-1 size-fraction <1 µm,liquid,D2O 99.9 Sigma-Aldrich,laboratory measurement,ATReflection,macroscopic,MIR,Mid-Infrared,corrected ATR absorbance","[{'subject': 'natural terrestrial'}, {'subject': 'phyllosilicate'}, {'subject': 'Na-exchanged smectite SWa-1 size-fraction <1 µm'}, {'subject': 'liquid'}, {'subject': 'D2O 99.9 Sigma-Aldrich'}, {'subject': 'laboratory measurement'}, {'subject': 'ATReflection'}, {'subject': 'macroscopic'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'corrected ATR absorbance'}]",['4 spectra'],['ASCII']
+10.26302/sshade/experiment_sb_20200430_001,Optical constants in the MIR and FIR for oriented hibonite crystals parallel and perpendicular to the c-axis,SSHADE/DOCCD (OSUG Data Center),2020.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2020-05-28T14:06:16.000Z,2020-05-28T14:06:17.000Z,inist.sshade,mgeg,"natural terrestrial,oxide-hydroxide,Hibonite,laboratory measurement,specular reflection,macroscopic,MIR,Mid-Infrared,FIR,Far-Infrared,optical constants","[{'subject': 'natural terrestrial'}, {'subject': 'oxide-hydroxide'}, {'subject': 'Hibonite'}, {'subject': 'laboratory measurement'}, {'subject': 'specular reflection'}, {'subject': 'macroscopic'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'FIR'}, {'subject': 'Far-Infrared'}, {'subject': 'optical constants'}]",['2 spectra'],['ASCII']
+10.26302/sshade/experiment_lb_20180326_001,"Vis-NIR reflectance spectra (i=0°, e=30°) of powdered lunar meteorite MAC88105 at 80°C under vacuum",SSHADE/GhoSST (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2021-05-02T05:49:02.000Z,2021-05-02T05:49:02.000Z,inist.sshade,mgeg,"extraterrestrial,lunar,anorthite,complex mineral mix,anorthositic lunar meteorite MAC88105,natural terrestrial,physically adsorbed phase,adsorbed H2O,laboratory measurement,bidirectional reflection,macroscopic,Vis,Visible,NIR,Near-Infrared,reflectance factor","[{'subject': 'extraterrestrial'}, {'subject': 'lunar'}, {'subject': 'anorthite'}, {'subject': 'complex mineral mix'}, {'subject': 'anorthositic lunar meteorite MAC88105'}, {'subject': 'natural terrestrial'}, {'subject': 'physically adsorbed phase'}, {'subject': 'adsorbed H2O'}, {'subject': 'laboratory measurement'}, {'subject': 'bidirectional reflection'}, {'subject': 'macroscopic'}, {'subject': 'Vis'}, {'subject': 'Visible'}, {'subject': 'NIR'}, {'subject': 'Near-Infrared'}, {'subject': 'reflectance factor'}]",['1 spectrum'],['ASCII']
+10.26302/sshade/experiment_rc_20200622_000,VIS reflectance spectra collected during electron irradiation experiments of compact slabs of salty ice prepared by slowly freezing solutions of NaCl with different concentrations.,SSHADE/BYPASS (OSUG Data Center),2023.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","Spherical salty ice particles are produced by spraying droplets of NaCl solutions into liquid nitrogen with the SPIPA-B setup and 9mm-thick samples are produced from this material. The samples are then introduced into the MEFISTO chamber, placed on a liquid nitrogen cooling plate, and the chamber is evacuated to high vacuum. The samples can then be bombarded with energetic electrons at different energies and fluxes and VIS hyperspectral images are collected.",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-07-31T13:29:37.000Z,2023-07-31T13:29:37.000Z,inist.sshade,mgeg,"laboratory measurement,biconical reflection,imaging,Vis,Visible,reflectance factor,water ice,NaCl hydrate,laboratory,inorganic molecular solid,chloride","[{'subject': 'laboratory measurement', 'subjectScheme': 'main'}, {'subject': 'biconical reflection', 'subjectScheme': 'main'}, {'subject': 'imaging', 'subjectScheme': 'main'}, {'subject': 'Vis', 'subjectScheme': 'variables'}, {'subject': 'Visible', 'subjectScheme': 'variables'}, {'subject': 'reflectance factor', 'subjectScheme': 'variables'}, {'subject': 'water ice', 'subjectScheme': 'name'}, {'subject': 'NaCl hydrate', 'subjectScheme': 'name'}, {'subject': 'laboratory', 'subjectScheme': 'origin'}, {'subject': 'inorganic molecular solid', 'subjectScheme': 'compound type'}, {'subject': 'chloride', 'subjectScheme': 'compound type'}]",['18 spectra'],['ASCII']
+10.26302/sshade/experiment_zed_20230519_01,MIR transmission spectra of eleven stratospheric IDPs,SSHADE/DAYSY (OSUG Data Center),2023.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",MIR spectroscopy of stratospheric IDPs in tranmission (sample crushed in a diamand compression cell),mds,True,findable,0.0,0.0,2.0,0.0,0.0,2023-05-25T10:18:00.000Z,2023-05-25T10:18:01.000Z,inist.sshade,mgeg,"laboratory measurement,transmission,micro-imaging,MIR,Mid-Infrared,Olivine,Pyroxene,extraterrestrial,nesosilicate,inosilicate,None,chondritic","[{'subject': 'laboratory measurement', 'subjectScheme': 'main'}, {'subject': 'transmission', 'subjectScheme': 'main'}, {'subject': 'micro-imaging', 'subjectScheme': 'main'}, {'subject': 'MIR', 'subjectScheme': 'variables'}, {'subject': 'Mid-Infrared', 'subjectScheme': 'variables'}, {'subject': 'Olivine', 'subjectScheme': 'name'}, {'subject': 'Pyroxene', 'subjectScheme': 'name'}, {'subject': 'extraterrestrial', 'subjectScheme': 'family'}, {'subject': 'nesosilicate', 'subjectScheme': 'compound type'}, {'subject': 'inosilicate', 'subjectScheme': 'compound type'}, {'subject': 'None', 'subjectScheme': 'meteorite group'}, {'subject': 'chondritic', 'subjectScheme': 'meteorite group'}]",['11 spectra'],['ASCII']
+10.26302/sshade/experiment_rc_20200616_001,"VIS reflectance spectra collected during electron irradiation experiments of salty ice particles (spherical, 67 µm average diameter) prepared by freezing solutions of NaCl with different concentrations.",SSHADE/BYPASS (OSUG Data Center),2023.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","Spherical salty ice particles are produced by spraying droplets of NaCl solutions into liquid nitrogen with the SPIPA-B setup and 9mm-thick samples are produced from this material. The samples are then introduced into the MEFISTO chamber, placed on a liquid nitrogen cooling plate, and the chamber is evacuated to high vacuum. The samples can then be bombarded with energetic electrons at different energies and fluxes and VIS hyperspectral images are collected.",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-07-31T13:27:11.000Z,2023-07-31T13:27:11.000Z,inist.sshade,mgeg,"laboratory measurement,biconical reflection,imaging,Vis,Visible,reflectance factor,water ice,NaCl hydrate,laboratory,inorganic molecular solid,chloride","[{'subject': 'laboratory measurement', 'subjectScheme': 'main'}, {'subject': 'biconical reflection', 'subjectScheme': 'main'}, {'subject': 'imaging', 'subjectScheme': 'main'}, {'subject': 'Vis', 'subjectScheme': 'variables'}, {'subject': 'Visible', 'subjectScheme': 'variables'}, {'subject': 'reflectance factor', 'subjectScheme': 'variables'}, {'subject': 'water ice', 'subjectScheme': 'name'}, {'subject': 'NaCl hydrate', 'subjectScheme': 'name'}, {'subject': 'laboratory', 'subjectScheme': 'origin'}, {'subject': 'inorganic molecular solid', 'subjectScheme': 'compound type'}, {'subject': 'chloride', 'subjectScheme': 'compound type'}]",['20 spectra'],['ASCII']
+10.26302/sshade/experiment_bs_20170830_001,Mid-IR transmission and optical constants spectra of crystalline C6H6 at 130K,SSHADE/GhoSST (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",Mid-IR transmission (thin film 1.65µm thick) and optical constants spectra of crystalline C6H6 at 130K,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2020-01-02T06:20:42.000Z,2020-01-02T06:20:42.000Z,inist.sshade,mgeg,"laboratory,organic molecular solid,C6H6 crystalline ice,laboratory measurement,transmission,macroscopic,MIR,Mid-Infrared,optical constants","[{'subject': 'laboratory'}, {'subject': 'organic molecular solid'}, {'subject': 'C6H6 crystalline ice'}, {'subject': 'laboratory measurement'}, {'subject': 'transmission'}, {'subject': 'macroscopic'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'optical constants'}]",['2 spectra'],['ASCII']
+10.26302/sshade/bandlist_abs_s2o_ar-matrix,Absorption band list of S2O in Ar matrix,SSHADE/BANDLIST (OSUG Data Center),2023.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",MIR absorption band list of the isotopes of $S_2O$ in Ar matrix,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-05-13T13:38:28.000Z,2023-05-13T13:38:29.000Z,inist.sshade,mgeg,"natural $S_2O$ in Ar matrix,Argon,Disulfur monoxide,solid alpha Argon,$\alpha$-phase,Argon,Disulfur monoxide,7440-37-1,20901-21-7,Ar,S2O,tridimentional covalent network solid,molecular solids with apolar molecules,elemental solid,absorption,MIR,band frequency,band width,band intensity,transition and vibration modes","[{'subject': 'natural $S_2O$ in Ar matrix', 'subjectScheme': 'name'}, {'subject': 'Argon', 'subjectScheme': 'name'}, {'subject': 'Disulfur monoxide', 'subjectScheme': 'name'}, {'subject': 'solid alpha Argon', 'subjectScheme': 'name'}, {'subject': '$\\alpha$-phase', 'subjectScheme': 'name'}, {'subject': 'Argon', 'subjectScheme': 'IUPAC name'}, {'subject': 'Disulfur monoxide', 'subjectScheme': 'IUPAC name'}, {'subject': '7440-37-1', 'subjectScheme': 'CAS number'}, {'subject': '20901-21-7', 'subjectScheme': 'CAS number'}, {'subject': 'Ar', 'subjectScheme': 'formula'}, {'subject': 'S2O', 'subjectScheme': 'formula'}, {'subject': 'tridimentional covalent network solid', 'subjectScheme': 'class'}, {'subject': 'molecular solids with apolar molecules', 'subjectScheme': 'class'}, {'subject': 'elemental solid', 'subjectScheme': 'compound type'}, {'subject': 'absorption', 'subjectScheme': 'variables'}, {'subject': 'MIR', 'subjectScheme': 'variables'}, {'subject': 'band frequency', 'subjectScheme': 'variables'}, {'subject': 'band width', 'subjectScheme': 'variables'}, {'subject': 'band intensity', 'subjectScheme': 'variables'}, {'subject': 'transition and vibration modes', 'subjectScheme': 'variables'}]",,['ASCII']
+10.26302/sshade/experiment_soc_20170316_001,Pd K edge XAS fluorescence of 1 wt.% Pd/SiO2 at RT under He or H2 (after heating at 300C under H2),SSHADE/FAME (OSUG Data Center),2021.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2021-07-20T12:05:33.000Z,2021-07-20T12:05:34.000Z,inist.sshade,mgeg,"laboratory,oxide,PdO,commercial,silicate,SiO2,solid,homopolymer,Cellulose,laboratory measurement,fluorescence emission,None,hard X,hard X-rays","[{'subject': 'laboratory'}, {'subject': 'oxide'}, {'subject': 'PdO'}, {'subject': 'commercial'}, {'subject': 'silicate'}, {'subject': 'SiO2'}, {'subject': 'solid'}, {'subject': 'homopolymer'}, {'subject': 'Cellulose'}, {'subject': 'laboratory measurement'}, {'subject': 'fluorescence emission'}, {'subject': 'None'}, {'subject': 'hard X'}, {'subject': 'hard X-rays'}]",['3 spectra'],['ASCII']
+10.15778/resif.rd,CEA/DASE broad-band permanent network in metropolitan France,RESIF - Réseau Sismologique et géodésique Français,2018.0,en,Dataset,"Open Access,Creative Commons Attribution 4.0 International","The CEA/DASE broad-band permanent network in metropolitan France is part of the operational services of the CEA dedicated to the monitoring of seismicity in metropolitan France. Since 2006, six sites have been used, corresponding to twelve station names (2 per station) due to change of station names. The six stations are included in the French national Broadband network and data from all stations is openly distributed through the RESIF datacenter.",mds,True,findable,0.0,0.0,0.0,8.0,0.0,2018-06-05T15:07:27.000Z,2018-06-05T15:07:27.000Z,inist.resif,vcob,"Broad Band,France","[{'subject': 'Broad Band'}, {'subject': 'France'}]",['Approximately 9 active stations; 100 Mb/day.'],"['Miniseed data', 'stationXML metadata']"
+10.15778/resif.3c2019,Le Teil P5 post seismic experiment,RESIF - Réseau Sismologique et géodésique Français,2019.0,en,Other,"Open Access,Creative Commons Attribution 4.0 International","Post seismic intervention following the Teil M5 earthquake (2019-11-11). One station (IRSN, Tricastin) contains the recording of the earthquake. Duration : about 3 months. 4 Centaur (CMG6T) from OCA, 6 Taurus (3 Episensor, 3 CMG40T) and 28 Fairfield nodes from SISMOB, 5 DM24 (CMG40T,CMG5T) from CEREMA 3 CMG6T from IRSN",mds,True,findable,0.0,0.0,1.0,0.0,0.0,2021-01-08T14:24:07.000Z,2021-01-11T09:39:39.000Z,inist.resif,vcob,"Le Teil d'Ardèche Mag 5.2,Le Teil 2019-11-11,Seismicity France,Montélimar,Post seismicity,broadband seismology,dense networks,nodes,Seismicity","[{'subject': ""Le Teil d'Ardèche Mag 5.2""}, {'subject': 'Le Teil 2019-11-11'}, {'subject': 'Seismicity France'}, {'subject': 'Montélimar'}, {'subject': 'Post seismicity'}, {'subject': 'broadband seismology'}, {'subject': 'dense networks'}, {'subject': 'nodes'}, {'subject': 'Seismicity'}]","['growing, 46 stations, 40 Mb per day per station during 3 mounths']","['Miniseed data', 'stationXML metadata']"
+10.5281/zenodo.10474700,MIPkit-A (MISOMIP2),Zenodo,2024.0,en,Dataset,Creative Commons Attribution 4.0 International,"Observational data gathered and reprocessed to facilitate the evaluation of ocean and ice-sheet models in the Amundsen Sea sector as part of MISOMIP2.
+
+ 
+
+__________________________________________
+
+This entire dataset should be cited as: 
+
+
+
+the MISOMIP2 MIPkit-A dataset (http://zenodo.org/doi/10.5281/zenodo.10062355) that includes data collected through multiple cruises of Nathaniel B. Palmer (United States Antarctic Program), James C. Ross (British Antarctic Survey and Natural Environment Research Council), Araon (Korea Polar Research Institute), Oden (Swedish Polar Research) and Polarstern (Alfred Wegener Institute, Germany), as well as regridded glaciological data from the MeaSUREs, MeaSUREs ITS_LIVE and CPOM projects
+
+
+For more specific use of some of the MIPkit-A data, we encourage people to cite the original data referenced below.
+
+ 
+
+__________________________________________
+
+IceSurfVel_MIPkitA_2000-2019 : annual maps of ice surface velocity
+
+Surface-parallel velocity vectors (in m/year) between 2000 and 2019 are provided on the common MISOMIP2 grid with regular grid spacing of 1 km. Data were calculated as a weighted average of all available Earth observation data from the MeaSUREs project (Rignot et al. 2014 and Mouginot et al. 2017) and MeaSUREs ITS_LIVE project (Gardner et al. 2022), with weights corresponding to the inverse square error of the original datasets. Propagated errors and a mask indicating the original data sources for each grid point are also included.
+
+ 
+
+__________________________________________
+
+IceSurfElChange_MIPkitA_1992-2019 : annual maps of surface elevation change
+
+Surface elevation changes (in m) between 1992 and 2019, relative to 16-Dec-2013, are provided on the common MISOMIP2 grid with regular grid spacing of 1 km. Data were calculated as a weighted average of available Earth observation data from CPOM (Otosaka al. 2023) and MeaSUREs ITS_LIVE (Nilsson et al. 2023) for the grounded ice and MeaSUREs ITS_LIVE data (Paolo et al. 2023) for floating ice. Propagated errors and a mask indicating the original data sources for each grid point are also included.
+
+ 
+
+__________________________________________
+
+Oce3d_MIPkitA_* : 3-dimensional temperature and salinity (horizontal slices every 100m)
+
+The hydrographic properties provided on horizontal sections at 15 depths come from the CTD measurements obtained during cruises of the following icebreaker research vessels: Nathaniel B. Palmer (United States Antarctic Program), James C. Ross (British Antarctic Survey and Natural Environment Research Council), Araon (Korea Polar Research Institute), Oden (Swedish Polar Research) and Polarstern (Alfred Wegener Institute, Germany). In this MIPkit, we have gathered data for the first months of 1994, 2000, 2007, 2009 (Jacobs, 1994, 2000, 2007, 2009), 2010 (Swedish Polar Research Secretariat 2010; Gohl 2015), 2012 (Kim et al. 2012), 2014 (Heywood 2014; Ha et al. 2014), 2016 (Kim et al. 2016), 2017 (Gohl 2017), 2018 (Kim et al. 2018), 2019 (Larter et al. 2019) and 2020 (Wellner, 2020).
+
+ 
+
+__________________________________________
+
+OceSec<n>_MIPkitA_* : vertical sections
+
+The first vertical (OceSec1) section where we provide hydrographic data in the Amundsen Sea starts across the continental shelf break and follows the Eastern Pine Island Trough southward until Pine Island Ice Shelf. This section was monitored by the following cruises: N.B. Palmer in January 2009, Polarstern in March 2010 and Araon in February-March 2012 (Jacobs et al. 2011; Gohl 2015; Dutrieux et al. 2014). The second vertical section (OceSec2) starts across the continental shelf break and follows the Dotson-Getz Trough southward until the Dotson Ice Shelf. It was monitored by the aforementioned Araon expeditions in 2010–2011 and early 2012 (Kim et al. 2017).
+
+The files OceSec<n>_model_lon_lat.csv contain the coordinates (longitude, latitude) at which model data should be interpolated to be compared to the observational sections.
+
+ 
+
+__________________________________________
+
+OceMoor<n>_MIPkitA_* : moorings
+
+The first mooring site (OceMoor1) is located near the northern part of the Pine Island ice shelf front (102.07°W, 74.87°S) and captures the thermocline variability from 2012 to 2018 (""iSTAR-8"" in NERC iSTAR program, and ""pig-n"" in NERC Ocean Forcing Ice Change Program). The second mooring site (OceMoor2)is located near the southern part of the Pine Island ice shelf front (102.15°W, 75.05°S), was monitored between 2009 and 2016, then in 2019–2020 through the following moorings: ""BSR-5"" (Buoy Supported Riser; Jacobs 2009), ""iSTAR-9"" (NERC iSTAR Program), and ""pig-s"" (NERC Ocean Forcing Ice Change Program). This second site experienced a strong deepening of the thermocline in 2012–2013 (Webber et al. 2017), then a more moderate deepening in 2016. These two mooring sites are located only 20 km from each other, show distinct mean thermocline depth and more consistent variability (Joughin et al. 2021).
+
+The third mooring observation (OceMoor3, ""trough-e"" in NERC Ocean Forcing Ice Change Program) used in MISOMIP is at the eastern Pine Island trough (102.55°W, 71.33°S). The eastern trough is considered to be the entrance of mCDW reaching the Pine Island Ice Shelf (Jacobs et al. 2011; Nakayama et al. 2013; Webber et al. 2017) but only two years of mooring observation was conducted from 2014-2015 due to important sea ice cover. The fourth mooring site (OceMoor4) used in MISOMIP is at the western Pine Island trough (113.05°W, 71.56°S). Several mooring observations were conducted within 2 km of each other, allowing us to observe thermocline variability from 2009 to 2016 with one year gap in 2011: ""BSR-12"" (Jacobs 2009), ""iSTAR-1"" (NERC iSTAR Program), and ""trough-w"" (NERC Ocean Forcing Ice Change Program).
+
+ 
+
+ 
+
+__________________________________________
+
+The archive example_routines.zip contains example of Matlab routines that were used to prepare the MIPkit-A ocean data, as well as GenerateData_MIPkit_Ice.m and writeNC_MIPkit_Ice.m that were used to process the MIPkit-A glaciological data.
+
+ 
+
+ 
+
+__________________________________________
+
+References
+
+Dutrieux, P., De Rydt, J., Jenkins, A., Holland, P. R., Ha, H. K., Lee, S. H., Steig, E. J., Ding, Q., Abrahamsen, E. P., and Schröder, M.: Strong sensitivity of Pine Island ice-shelf melting to climatic variability, Science, 343, 174–178, 2014.
+
+Gohl, K.: Station list and links to master tracks in different resolutions of POLARSTERN cruise ANT-XXVI/3, Wellington - Punta Arenas, 2010-01-30 - 2010-04-05, Tech. rep., Alfred Wegener Institute, Helmholtz Centre for Polar and Marine Research, Bremerhaven, https://doi.org/10.1594/PANGAEA.847944, 2015.
+
+Gohl, K.: The Expedition PS104 of the Research Vessel POLARSTERN to the Amundsen Sea in 2017, Reports on polar and marine research, Tech. rep., Alfred Wegener Institute for Polar and Marine Research, Bremerhaven, http://doi.org/10.2312/BzPM_0712_2017, 2017.
+
+Ha, H. K., Kim, T. W., Lee, H. J., Kang, C. Y., Hong, C. S., Wåhlin, A. K., Rolandsson, J., Karen, O., and Miles, T.: The Amundsen Sea Expedition (ANA04B): IBRV Araon, 24 December 2013 – 25 January 2014 – Chapther 1: Physical Oceanography, Tech. rep., Korea Polar Research Institute, Incheon, https://repository.kopri.re.kr/handle/201206/4605, 2014.
+
+Heywood, K. 690 J.: JR294/295 Cruise Report, Ice Sheet Stability Programme (iSTAR), RRS James Clark Ross, 26th February – 8th March 2014, Amundsen Sea, Tech. rep., Natural Environment Research Council (NERC), https://www.bodc.ac.uk/resources/inventories/cruise_inventory/report/13405/, 2014.
+
+Jacobs, S.: Cruise NBP9402, RVIB Nathaniel B. Palmer, Feb 14 – Apr 5 1994, Tech. rep., United States Antarctic Program. http://doi.org/10.7284/905397, 1994.
+
+Jacobs, S.: Cruise NBP0001, RVIB Nathaniel B. Palmer, Feb 15 – Apr 1 2000, Tech. rep., United States Antarctic Program. http://doi.org/10.7284/905450, 2000.
+
+Jacobs, S.: Cruise NBP0702, RVIB Nathaniel B. Palmer, Feb 03 – Mar 25 2007, Tech. rep., United States Antarctic Program. http://doi.org/10.7284/905530, 2007.
+
+Jacobs, S.: Cruise NBP0901, RVIB Nathaniel B. Palmer, Jan 05 – Feb 26 2009, Tech. rep., United States Antarctic Program, http://doi.org/10.7284/905547, 2009.
+
+Jacobs, S. S., Jenkins, A., Giulivi, C. F., and Dutrieux, P.: Stronger ocean circulation and increased melting under Pine Island Glacier ice shelf, Nature Geoscience, 4, 519–523, 2011.
+
+Joughin, I., Shapero, D., Smith, B., Dutrieux, P., and Barham, M.: Ice-shelf retreat drives recent Pine Island Glacier speedup, Science Advances, 7, eabg3080, 2021.
+
+Kim, T. W., H, H. K., and Hong, C. S.: The Amundsen Sea Expedition (ANA02C): IBRV Araon, 31 January 2012 – 20 March 2012 – Chapther 1: Hydrographic Survey, Tech. rep., Korea Polar Research Institute, Incheon, https://repository.kopri.re.kr/handle/201206/4603, 2012.
+
+Kim, T. W., Cho, K. H., Kim, C. S., Yang, H. W., La, H. S., Lee, J. H., Kim, D. K., Jung, J. H., Wåhlin, A. K., Assmann, K. M., Darelius, E., Abrahamsen, E. P., and Waite, N.: The Amundsen Sea Expedition (ANA06B): IBRV Araon, 6 January – 23 February 2016 – Chapther 1: Physical Oceanography in Amundsen Sea, Tech. rep., Korea Polar Research Institute, Incheon, https://ftp.nmdc.no/nmdc/UIB/Mooring/20181213/ANA06B_cruise_report.pdf, 2016.
+
+Kim, T.-W., Ha, H. K., Wåhlin, A. K., Lee, S., Kim, C.-S., Lee, J. H., and Cho, Y.-K.: Is Ekman pumping responsible for the seasonal variation of warm circumpolar deep water in the Amundsen Sea?, Continental Shelf Research, 132, 38–48, 2017.
+
+Kim, T. W., Cho, K. H., Park, T. W., Yang, H. W., Kim, Y., Assmann, K. M., Rolandsson, J., Dutrieux, P., Gobat, J., Beem, L., Richter, T., Buhl, D., and Durand, I.: The Amundsen Sea Expedition (ANA08B): IBRV Araon, 21 December 2017 – 13 February 2018 – Chapther 1: Physical Oceanography, Tech. rep., Korea Polar Research Institute, Incheon, https://repository.kopri.re.kr/handle/201206/9441, 2018.
+
+Larter, R., Barham, M., Boehme, L., Braddock, S., Graham, A., Hogan, K., Mazur, A., Minzoni, R., Queste, B., Sheehan, P., Spoth, M., Wåhlin, A., Bortolotto-d'Oliveira, G., Clark, R. W., Fitzgerald, V., Karam, S., Kirkham, J., Stedt, F., Zheng, Y., Beeler, C., Goodell, J., Rush, E., Snow, T., Welzenbach, L., Andersson, J., and Rolandsson, J.: Cruise NBP1902, RVIB Nathaniel B. Palmer, Jan 29 – Mar 25 2019, Tech. rep., United States Antarctic Program, http://doi.org/10.7284/908147, 2019.
+
+Nakayama, Y., Schröder, M., and Hellmer, H. H.: From circumpolar deep water to the glacial meltwater plume on the eastern Amundsen Shelf, Deep Sea Res. I, 77, 50–62, 2013.
+
+Swedish Polar Research Secretariat: Oden Southern Ocean 2009/10 - Conductivity-Temperature-Depth (CTD) Data Collected Onboard Icebreaker Oden during February through March 2010, Tech. rep., Swedish Polar Research, http://snd.gu.se/en/catalogue/dataset/ecds0220-1, 2010.
+
+Webber, B. G. M., Heywood, K. J., Stevens, D. P., Dutrieux, P., Abrahamsen, E. P., Jenkins, A., Jacobs, S. S., Ha, H. K., Lee, S. H., and Kim, T. W.: Mechanisms driving variability in the ocean forcing of Pine Island Glacier, Nature Communications, 8, 1–8, 2017.
+
+Wellner, J.: Cruise NBP2002, RVIB Nathaniel B. Palmer, Jan 25 2020 – Mar 08 2020, Tech. rep., United States Antarctic Program, http://doi.org/10.7284/908803, 2019.",api,True,findable,0.0,0.0,0.0,0.0,0.0,2024-01-09T15:27:46.000Z,2024-01-09T15:27:46.000Z,cern.zenodo,cern,,,,
+10.26302/sshade/bandlist_abs_c4h2_am-c4h2,Absorption band list of C4H2 in natural solid C4H2 (amorphous phase),SSHADE/BANDLIST (OSUG Data Center),2023.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",MIR absorption band list of $C_4H_2$ in natural solid $C_4H_2$ (amorphous phase) at 10 K,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-04-30T10:29:34.000Z,2023-04-30T10:29:35.000Z,inist.sshade,mgeg,"natural C4H2 - amorphous,Diacetylene,amorphous Diacetylene,amorphous C4H2,Buta-1,3-diyne,460-12-8,C4H2,non polar molecular solid,molecular solids with apolar molecules,organic molecular solid,absorption,MIR,band frequency,band width,band intensity,transition and vibration modes","[{'subject': 'natural C4H2 - amorphous', 'subjectScheme': 'name'}, {'subject': 'Diacetylene', 'subjectScheme': 'name'}, {'subject': 'amorphous Diacetylene', 'subjectScheme': 'name'}, {'subject': 'amorphous C4H2', 'subjectScheme': 'name'}, {'subject': 'Buta-1,3-diyne', 'subjectScheme': 'IUPAC name'}, {'subject': '460-12-8', 'subjectScheme': 'CAS number'}, {'subject': 'C4H2', 'subjectScheme': 'formula'}, {'subject': 'non polar molecular solid', 'subjectScheme': 'class'}, {'subject': 'molecular solids with apolar molecules', 'subjectScheme': 'class'}, {'subject': 'organic molecular solid', 'subjectScheme': 'compound type'}, {'subject': 'absorption', 'subjectScheme': 'var'}, {'subject': 'MIR', 'subjectScheme': 'var'}, {'subject': 'band frequency', 'subjectScheme': 'var'}, {'subject': 'band width', 'subjectScheme': 'var'}, {'subject': 'band intensity', 'subjectScheme': 'var'}, {'subject': 'transition and vibration modes', 'subjectScheme': 'var'}]",,['ASCII']
+10.26302/sshade/experiment_sr_20200204_03,$Ar^+$ irradiation of phyllosilicate pellets probed by Vis-NIR spectroscopy,SSHADE/DAYSY (OSUG Data Center),2022.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",Visible and Near-IR spectra of phyllosilicate pellets at different irradiation fluences of $Ar^+$ (40 keV).,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2022-06-06T12:36:07.000Z,2022-06-06T12:36:08.000Z,inist.sshade,mgeg,"mineral,natural terrestrial,phyllosilicate,Serpentine Rawhide,Serpentine UB-N,Saponite Griffithite,laboratory measurement,bidirectional reflection,microscopy,Vis,Visible,macroscopic,NIR,Near-Infrared,bidirectional reflectance","[{'subject': 'mineral'}, {'subject': 'natural terrestrial'}, {'subject': 'phyllosilicate'}, {'subject': 'Serpentine Rawhide'}, {'subject': 'Serpentine UB-N'}, {'subject': 'Saponite Griffithite'}, {'subject': 'laboratory measurement'}, {'subject': 'bidirectional reflection'}, {'subject': 'microscopy'}, {'subject': 'Vis'}, {'subject': 'Visible'}, {'subject': 'macroscopic'}, {'subject': 'NIR'}, {'subject': 'Near-Infrared'}, {'subject': 'bidirectional reflectance'}]",['12 spectra'],['ASCII']
+10.6084/m9.figshare.22735399,"Additional file 1 of Multiple trauma in pregnant women: injury assessment, fetal radiation exposure and mortality. A multicentre observational study",figshare,2023.0,,Text,Creative Commons Attribution 4.0 International,Supplementary Material 1,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-05-03T03:19:15.000Z,2023-05-03T03:19:15.000Z,figshare.ars,otjm,"Medicine,Cell Biology,Biotechnology,69999 Biological Sciences not elsewhere classified,FOS: Biological sciences,19999 Mathematical Sciences not elsewhere classified,FOS: Mathematics,Developmental Biology,Science Policy","[{'subject': 'Medicine'}, {'subject': 'Cell Biology'}, {'subject': 'Biotechnology'}, {'subject': '69999 Biological Sciences not elsewhere classified', 'schemeUri': 'http://www.abs.gov.au/ausstats/abs@.nsf/0/6BB427AB9696C225CA2574180004463E', 'subjectScheme': 'FOR'}, {'subject': 'FOS: Biological sciences', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': '19999 Mathematical Sciences not elsewhere classified', 'schemeUri': 'http://www.abs.gov.au/ausstats/abs@.nsf/0/6BB427AB9696C225CA2574180004463E', 'subjectScheme': 'FOR'}, {'subject': 'FOS: Mathematics', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': 'Developmental Biology'}, {'subject': 'Science Policy'}]",['675112 Bytes'],
+10.5281/zenodo.10475278,DBnary - Wiktionary Lexical Data in RDF/Ontolex - All languages,Zenodo,2023.0,mul,Dataset,Creative Commons Attribution 4.0 International,"The DBnary dataset is an extract of Wiktionary data from many language editions in RDF Format. Since July 1st 2017, the lexical data extracted from Wiktionary is modelled using the Ontolex vocabulary.
+This dataset contains all language data (in 2023, 25 language editions are supported) and contains one version per Wikimedia dump (one version twice a month).",api,True,findable,0.0,0.0,0.0,0.0,0.0,2024-01-09T15:40:33.000Z,2024-01-09T15:40:33.000Z,cern.zenodo,cern,"Wiktionary,LLOD,Linguistic Linked Open Data,Ontolex,RDF","[{'subject': 'Wiktionary'}, {'subject': 'LLOD'}, {'subject': 'Linguistic Linked Open Data'}, {'subject': 'Ontolex'}, {'subject': 'RDF'}]",,
+10.6084/m9.figshare.22655339,Additional file 1 of ICU admission for solid cancer patients treated with immune checkpoint inhibitors,figshare,2023.0,,Text,Creative Commons Attribution 4.0 International,Additional file 1: Table S1. World Health Organization-Uppsala Monitoring Centre (WHO-UMC) causality categories. Table S2. Diagnosis at ICU admission according to proposed IrAE causality at ICU discharge (n = 110 patients).,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-04-19T03:54:41.000Z,2023-04-19T03:54:42.000Z,figshare.ars,otjm,"Medicine,Pharmacology,Biotechnology,39999 Chemical Sciences not elsewhere classified,FOS: Chemical sciences,Immunology,FOS: Clinical medicine,Cancer","[{'subject': 'Medicine'}, {'subject': 'Pharmacology'}, {'subject': 'Biotechnology'}, {'subject': '39999 Chemical Sciences not elsewhere classified', 'schemeUri': 'http://www.abs.gov.au/ausstats/abs@.nsf/0/6BB427AB9696C225CA2574180004463E', 'subjectScheme': 'FOR'}, {'subject': 'FOS: Chemical sciences', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': 'Immunology'}, {'subject': 'FOS: Clinical medicine', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': 'Cancer'}]",['16958 Bytes'],
+10.26302/sshade/experiment_ik_20180418_002,Ce L3 edge XAS HERFD of Ce3+ acetate at 10K,SSHADE/FAME (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2019-12-05T14:40:50.000Z,2019-12-05T14:40:51.000Z,inist.sshade,mgeg,"solid,commercial,non-oxide ceramic,BN powder,organic salt,Ce3+ acetate,laboratory measurement,fluorescence emission,None,hard X,hard X-rays","[{'subject': 'solid'}, {'subject': 'commercial'}, {'subject': 'non-oxide ceramic'}, {'subject': 'BN powder'}, {'subject': 'organic salt'}, {'subject': 'Ce3+ acetate'}, {'subject': 'laboratory measurement'}, {'subject': 'fluorescence emission'}, {'subject': 'None'}, {'subject': 'hard X'}, {'subject': 'hard X-rays'}]",['1 spectrum'],['ASCII']
+10.6084/m9.figshare.22735503,Additional file 1 of Healthcare students’ prevention training in a sanitary service: analysis of health education interventions in schools of the Grenoble academy,figshare,2023.0,,Text,Creative Commons Attribution 4.0 International,Supplementary Material 1,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-05-03T03:20:26.000Z,2023-05-03T03:20:27.000Z,figshare.ars,otjm,"Medicine,Biotechnology,69999 Biological Sciences not elsewhere classified,FOS: Biological sciences,Science Policy","[{'subject': 'Medicine'}, {'subject': 'Biotechnology'}, {'subject': '69999 Biological Sciences not elsewhere classified', 'schemeUri': 'http://www.abs.gov.au/ausstats/abs@.nsf/0/6BB427AB9696C225CA2574180004463E', 'subjectScheme': 'FOR'}, {'subject': 'FOS: Biological sciences', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': 'Science Policy'}]",['19715 Bytes'],
+10.26302/sshade/experiment_lb_20191211_003,Fe K edge XAS transmission of bulk CR carbonaceous chondrites,SSHADE/GhoSST+FAME (OSUG Data Center),2020.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",raw and normalized Fe K edge XAS transmission of bulk CR carbonaceous chondrites,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2019-12-13T13:05:04.000Z,2019-12-13T13:05:05.000Z,inist.sshade,mgeg,"solid,commercial,non-oxide ceramic,BN powder,extraterrestrial,carbonaceous chondrite,CR,complex organic-mineral mix,matrix EET92159,complex mineral mix,chondrules EET92159,CAIs EET92159,matrix GRA06100 IPAG,chondrules GRA06100 IPAG,CAIs GRA06100 IPAG,matrix GRO03116 IPAG,chondrules GRO03116 IPAG,CAIs GRO03116 IPAG,matrix GRO95577 IPAG,chondrules GRO95577 IPAG,CAIs GRO95577 IPAG,matrix LAP04516,chondrules LAP04516,CAIs LAP04516,matrix MET00426,chondrules MET00426,CAIs MET00426,matrix EET92042,chondrules EET92042,CAIs EET92042,matrix GRA95229,chondrules GRA95229,CAIs GRA95229,matrix RENAZZO,chondrules RENAZZO,CAIs RENAZZO,laboratory measurement,transmission,None,hard X,raw,normalized absorbance","[{'subject': 'solid'}, {'subject': 'commercial'}, {'subject': 'non-oxide ceramic'}, {'subject': 'BN powder'}, {'subject': 'extraterrestrial'}, {'subject': 'carbonaceous chondrite'}, {'subject': 'CR'}, {'subject': 'complex organic-mineral mix'}, {'subject': 'matrix EET92159'}, {'subject': 'complex mineral mix'}, {'subject': 'chondrules EET92159'}, {'subject': 'CAIs EET92159'}, {'subject': 'matrix GRA06100 IPAG'}, {'subject': 'chondrules GRA06100 IPAG'}, {'subject': 'CAIs GRA06100 IPAG'}, {'subject': 'matrix GRO03116 IPAG'}, {'subject': 'chondrules GRO03116 IPAG'}, {'subject': 'CAIs GRO03116 IPAG'}, {'subject': 'matrix GRO95577 IPAG'}, {'subject': 'chondrules GRO95577 IPAG'}, {'subject': 'CAIs GRO95577 IPAG'}, {'subject': 'matrix LAP04516'}, {'subject': 'chondrules LAP04516'}, {'subject': 'CAIs LAP04516'}, {'subject': 'matrix MET00426'}, {'subject': 'chondrules MET00426'}, {'subject': 'CAIs MET00426'}, {'subject': 'matrix EET92042'}, {'subject': 'chondrules EET92042'}, {'subject': 'CAIs EET92042'}, {'subject': 'matrix GRA95229'}, {'subject': 'chondrules GRA95229'}, {'subject': 'CAIs GRA95229'}, {'subject': 'matrix RENAZZO'}, {'subject': 'chondrules RENAZZO'}, {'subject': 'CAIs RENAZZO'}, {'subject': 'laboratory measurement'}, {'subject': 'transmission'}, {'subject': 'None'}, {'subject': 'hard X'}, {'subject': 'raw'}, {'subject': 'normalized absorbance'}]",['18 spectra'],['ASCII']
+10.6084/m9.figshare.22807641,Additional file 2 of Phenotype and imaging features associated with APP duplications,figshare,2023.0,,Image,Creative Commons Attribution 4.0 International,Additional file 2: Supp Figure 2. MRI scans of three patients from the BES_262 family showing the large heterogeneity of cerebral imaging. A: MRI of 262-001; B: MRI of 262-003; C: MRI of 262-004.,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-05-12T03:40:50.000Z,2023-05-12T03:40:51.000Z,figshare.ars,otjm,"Biochemistry,Medicine,Cell Biology,Neuroscience,Science Policy","[{'subject': 'Biochemistry'}, {'subject': 'Medicine'}, {'subject': 'Cell Biology'}, {'subject': 'Neuroscience'}, {'subject': 'Science Policy'}]",['779176 Bytes'],
+10.26302/sshade/experiment_ak_20141031_1,Mid-infrared attenuated total reflectance experiment with Na+ exchanged less 0.1 μm size fraction of montmorillonite (SWy-2) equilibrated with H2O vapor under variable relative humidity,SSHADE/LSD (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2022-11-04T08:10:37.000Z,2022-11-04T08:10:38.000Z,inist.sshade,mgeg,"natural terrestrial,phyllosilicate,Na-exchanged montmorillonite SWy-2 size-fraction &lt;0.1 µm,liquid,H2O deionized,laboratory measurement,ATReflection,macroscopic,MIR,Mid-Infrared,corrected ATR absorbance","[{'subject': 'natural terrestrial'}, {'subject': 'phyllosilicate'}, {'subject': 'Na-exchanged montmorillonite SWy-2 size-fraction &lt;0.1 µm'}, {'subject': 'liquid'}, {'subject': 'H2O deionized'}, {'subject': 'laboratory measurement'}, {'subject': 'ATReflection'}, {'subject': 'macroscopic'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'corrected ATR absorbance'}]",['6 spectra'],['ASCII']
+10.26302/sshade/bandlist_abs_n2_beta-n2,Absorption band list of N2 in natural solid N2 (phase beta),SSHADE/BANDLIST (OSUG Data Center),2023.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",MIR-NIR absorption band list of the isotopes of $N_2$ in natural solid $\beta-N2$,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-05-08T14:52:47.000Z,2023-05-08T14:52:47.000Z,inist.sshade,mgeg,"natural N2 - phase beta,Nitrogen,Solid beta Nitrogen,$\beta$-phase,Dinitrogen,7727-37-9,N2,non polar molecular solid,molecular solids with apolar molecules,inorganic molecular solid,absorption,NIR,MIR,band frequency,band width,band intensity,transition and vibration modes","[{'subject': 'natural N2 - phase beta', 'subjectScheme': 'name'}, {'subject': 'Nitrogen', 'subjectScheme': 'name'}, {'subject': 'Solid beta Nitrogen', 'subjectScheme': 'name'}, {'subject': '$\\beta$-phase', 'subjectScheme': 'name'}, {'subject': 'Dinitrogen', 'subjectScheme': 'IUPAC name'}, {'subject': '7727-37-9', 'subjectScheme': 'CAS number'}, {'subject': 'N2', 'subjectScheme': 'formula'}, {'subject': 'non polar molecular solid', 'subjectScheme': 'class'}, {'subject': 'molecular solids with apolar molecules', 'subjectScheme': 'class'}, {'subject': 'inorganic molecular solid', 'subjectScheme': 'compound type'}, {'subject': 'absorption', 'subjectScheme': 'var'}, {'subject': 'NIR', 'subjectScheme': 'var'}, {'subject': 'MIR', 'subjectScheme': 'var'}, {'subject': 'band frequency', 'subjectScheme': 'var'}, {'subject': 'band width', 'subjectScheme': 'var'}, {'subject': 'band intensity', 'subjectScheme': 'var'}, {'subject': 'transition and vibration modes', 'subjectScheme': 'var'}]",,['ASCII']
+10.26302/sshade/experiment_bs_20200422_100,"Vis-NIR reflectance spectra of Bordezac pigments (Pig_0160_D): blocks, powders, plots and painted matters",SSHADE/PIG (OSUG Data Center),2021.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","Vis-NIR reflectance spectra of Bordezac pigments (Pig_0160_D) as 2 raw blocks and 1 sawn (2 faces each), as a powder with grain sizes &lt; 160 µm (2 densities: 0.91 and 1.53 g/cm3), as a polished plot and a painted matter on limestone",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2020-08-28T04:51:37.000Z,2020-08-28T04:51:38.000Z,inist.sshade,mgeg,"mineral,natural terrestrial,tektosilicate,Quartz,phyllosilicate,Muscovite,phosphate,Xenotime-(Y),sulfate,Baryte,oxide-hydroxide,Hematite,carbonate,limestone,laboratory measurement,bidirectional reflection,macroscopic,Vis,Visible,NIR,Near-Infrared,reflectance factor","[{'subject': 'mineral'}, {'subject': 'natural terrestrial'}, {'subject': 'tektosilicate'}, {'subject': 'Quartz'}, {'subject': 'phyllosilicate'}, {'subject': 'Muscovite'}, {'subject': 'phosphate'}, {'subject': 'Xenotime-(Y)'}, {'subject': 'sulfate'}, {'subject': 'Baryte'}, {'subject': 'oxide-hydroxide'}, {'subject': 'Hematite'}, {'subject': 'carbonate'}, {'subject': 'limestone'}, {'subject': 'laboratory measurement'}, {'subject': 'bidirectional reflection'}, {'subject': 'macroscopic'}, {'subject': 'Vis'}, {'subject': 'Visible'}, {'subject': 'NIR'}, {'subject': 'Near-Infrared'}, {'subject': 'reflectance factor'}]",['10 spectra'],['ASCII']
+10.26302/sshade/bandlist_raman_fe-dolomite,Raman bandlist of natural Ferroan Dolomite,SSHADE/BANDLIST (OSUG Data Center),2023.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",MIR-FIR Raman bandlist of natural Ferroan Dolomite (Fe &lt; Mg) at 295K,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-08-27T13:42:26.000Z,2023-08-27T13:42:27.000Z,inist.sshade,mgeg,"Ferroan Dolomite,Calcium,Iron(II) cation,Magnesium,Manganese(II) cation,Carbonate anion,Dolomite,Calcium,Iron(2+) cation,Magnesium,Manganese(2+) cation,7440-70-2,15438-31-0,7439-95-4,16397-91-4,Ca,Fe2+,Mg,Mn2+,(CO3)2-,CaMg(CO3)2,Dolomite,non-silicate mineral,carbonate,carbonates, nitrates, borates,anhydrous carbonates,Norsethite Group,14.02.01.01,05.AB.10,Raman scattering,FIR,MIR,band frequency,band width,band intensity,transition and vibration modes","[{'subject': 'Ferroan Dolomite', 'subjectScheme': 'name'}, {'subject': 'Calcium', 'subjectScheme': 'name'}, {'subject': 'Iron(II) cation', 'subjectScheme': 'name'}, {'subject': 'Magnesium', 'subjectScheme': 'name'}, {'subject': 'Manganese(II) cation', 'subjectScheme': 'name'}, {'subject': 'Carbonate anion', 'subjectScheme': 'name'}, {'subject': 'Dolomite', 'subjectScheme': 'name'}, {'subject': 'Calcium', 'subjectScheme': 'IUPAC name'}, {'subject': 'Iron(2+) cation', 'subjectScheme': 'IUPAC name'}, {'subject': 'Magnesium', 'subjectScheme': 'IUPAC name'}, {'subject': 'Manganese(2+) cation', 'subjectScheme': 'IUPAC name'}, {'subject': '7440-70-2', 'subjectScheme': 'CAS number'}, {'subject': '15438-31-0', 'subjectScheme': 'CAS number'}, {'subject': '7439-95-4', 'subjectScheme': 'CAS number'}, {'subject': '16397-91-4', 'subjectScheme': 'CAS number'}, {'subject': 'Ca', 'subjectScheme': 'formula'}, {'subject': 'Fe2+', 'subjectScheme': 'formula'}, {'subject': 'Mg', 'subjectScheme': 'formula'}, {'subject': 'Mn2+', 'subjectScheme': 'formula'}, {'subject': '(CO3)2-', 'subjectScheme': 'formula'}, {'subject': 'CaMg(CO3)2', 'subjectScheme': 'formula'}, {'subject': 'Dolomite', 'subjectScheme': 'IMA name'}, {'subject': 'non-silicate mineral', 'subjectScheme': 'mineral class'}, {'subject': 'carbonate', 'subjectScheme': 'compound type'}, {'subject': 'carbonates, nitrates, borates', 'subjectScheme': 'Dana class'}, {'subject': 'anhydrous carbonates', 'subjectScheme': 'Dana class'}, {'subject': 'Norsethite Group', 'subjectScheme': 'Dana group'}, {'subject': '14.02.01.01', 'subjectScheme': 'Dana code'}, {'subject': '05.AB.10', 'subjectScheme': 'Strunz code'}, {'subject': 'Raman scattering', 'subjectScheme': 'variables'}, {'subject': 'FIR', 'subjectScheme': 'variables'}, {'subject': 'MIR', 'subjectScheme': 'variables'}, {'subject': 'band frequency', 'subjectScheme': 'variables'}, {'subject': 'band width', 'subjectScheme': 'variables'}, {'subject': 'band intensity', 'subjectScheme': 'variables'}, {'subject': 'transition and vibration modes', 'subjectScheme': 'variables'}]",,['ASCII']
+10.26302/sshade/experiment_sb_20190819_001,Optical constants from UV to FIR for 6 Fe(II) and Fe(II)-Mg-oxides,SSHADE/DOCCD (OSUG Data Center),2019.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2020-04-20T13:09:19.000Z,2020-04-20T13:09:20.000Z,inist.sshade,mgeg,"laboratory,oxide-hydroxide,FeO,(Fe,Mg)O, stoichiometric Fe content 0.9,(Fe,Mg)O, stoichiometric Fe content 0.8,(Fe,Mg)O, stoichiometric Fe content 0.7,(Fe,Mg)O, stoichiometric Fe content 0.5,(Fe,Mg)O, stoichiometric Fe content 0.4,laboratory measurement,specular reflection,macroscopic,UV,Ultraviolet,Vis,Visible,NIR,Near-Infrared,MIR,Mid-Infrared,FIR,Far-Infrared,optical constants","[{'subject': 'laboratory'}, {'subject': 'oxide-hydroxide'}, {'subject': 'FeO'}, {'subject': '(Fe,Mg)O, stoichiometric Fe content 0.9'}, {'subject': '(Fe,Mg)O, stoichiometric Fe content 0.8'}, {'subject': '(Fe,Mg)O, stoichiometric Fe content 0.7'}, {'subject': '(Fe,Mg)O, stoichiometric Fe content 0.5'}, {'subject': '(Fe,Mg)O, stoichiometric Fe content 0.4'}, {'subject': 'laboratory measurement'}, {'subject': 'specular reflection'}, {'subject': 'macroscopic'}, {'subject': 'UV'}, {'subject': 'Ultraviolet'}, {'subject': 'Vis'}, {'subject': 'Visible'}, {'subject': 'NIR'}, {'subject': 'Near-Infrared'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'FIR'}, {'subject': 'Far-Infrared'}, {'subject': 'optical constants'}]",['6 spectra'],['ASCII']
+10.26302/sshade/experiment_jf_20220531_001,"Visible near infrared spectra of rocks from the Solfatara crater, Phlegrean fields, Italy",SSHADE/Mirabelle (OSUG Data Center),2022.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","Visible near infrared spectra of rocks from the Solfatara crater, Phlegrean fields, Italy",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2022-07-28T15:00:47.000Z,2022-07-28T15:00:48.000Z,inist.sshade,mgeg,"solid,natural terrestrial,tektosilicate,Opal,oxide-hydroxide,Anatase,carbonate,Calcite,elemental mineral,Sulfur,sulfate,Alunite,Alunogen,Alum-(K),Mercallite,Yavapaiite,Goldichite,Coquimbite,Tamarugite,Jarosite,Hematite,phyllosilicate,Kaolinite,sulfide,Realgar,Cinnabar,Orpiment,field measurement,biconical reflection,macroscopic,Vis,Visible,NIR,Near-Infrared,normalized reflectance","[{'subject': 'solid'}, {'subject': 'natural terrestrial'}, {'subject': 'tektosilicate'}, {'subject': 'Opal'}, {'subject': 'oxide-hydroxide'}, {'subject': 'Anatase'}, {'subject': 'carbonate'}, {'subject': 'Calcite'}, {'subject': 'elemental mineral'}, {'subject': 'Sulfur'}, {'subject': 'sulfate'}, {'subject': 'Alunite'}, {'subject': 'Alunogen'}, {'subject': 'Alum-(K)'}, {'subject': 'Mercallite'}, {'subject': 'Yavapaiite'}, {'subject': 'Goldichite'}, {'subject': 'Coquimbite'}, {'subject': 'Tamarugite'}, {'subject': 'Jarosite'}, {'subject': 'Hematite'}, {'subject': 'phyllosilicate'}, {'subject': 'Kaolinite'}, {'subject': 'sulfide'}, {'subject': 'Realgar'}, {'subject': 'Cinnabar'}, {'subject': 'Orpiment'}, {'subject': 'field measurement'}, {'subject': 'biconical reflection'}, {'subject': 'macroscopic'}, {'subject': 'Vis'}, {'subject': 'Visible'}, {'subject': 'NIR'}, {'subject': 'Near-Infrared'}, {'subject': 'normalized reflectance'}]",['23 spectra'],['ASCII']
+10.26302/sshade/experiment_bs_20231304_001,Near-infrared BRDF spectra in the principal plane of Salammoniac and Mascagnite 32-80µm grain size powders at 300K,SSHADE/CSS (OSUG Data Center),2023.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","Near-infrared BRDF spectra in the principal plane (i=0, 30, 60°; e= -70, -60, -40, -20, 0, 20, 40, 60, 70°) of Salammoniac and Mascagnite 32-80µm grain size powders at 300K",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-05-25T08:58:11.000Z,2023-05-25T08:58:11.000Z,inist.sshade,mgeg,"laboratory measurement,bidirectional reflection,macroscopic,NIR,Near-Infrared,reflectance factor,Salammoniac,Mascagnite,natural terrestrial,halide,sulfate","[{'subject': 'laboratory measurement', 'subjectScheme': 'main'}, {'subject': 'bidirectional reflection', 'subjectScheme': 'main'}, {'subject': 'macroscopic', 'subjectScheme': 'main'}, {'subject': 'NIR', 'subjectScheme': 'variables'}, {'subject': 'Near-Infrared', 'subjectScheme': 'variables'}, {'subject': 'reflectance factor', 'subjectScheme': 'variables'}, {'subject': 'Salammoniac', 'subjectScheme': 'name'}, {'subject': 'Mascagnite', 'subjectScheme': 'name'}, {'subject': 'natural terrestrial', 'subjectScheme': 'origin'}, {'subject': 'halide', 'subjectScheme': 'compound type'}, {'subject': 'sulfate', 'subjectScheme': 'compound type'}]",['2 spectra'],['ASCII']
+10.26302/sshade/experiment_op_20180717_002,Cu K edge XAS HERFD (Kalpha1) of CuSO4.n(H2O) at ambient conditions,SSHADE/FAME (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2019-12-05T13:35:39.000Z,2019-12-05T13:35:39.000Z,inist.sshade,mgeg,"solid,commercial,non-oxide ceramic,BN powder,laboratory,None,CuSO4.n(H2O),laboratory measurement,fluorescence emission,hard X,hard X-rays","[{'subject': 'solid'}, {'subject': 'commercial'}, {'subject': 'non-oxide ceramic'}, {'subject': 'BN powder'}, {'subject': 'laboratory'}, {'subject': 'None'}, {'subject': 'CuSO4.n(H2O)'}, {'subject': 'laboratory measurement'}, {'subject': 'fluorescence emission'}, {'subject': 'hard X'}, {'subject': 'hard X-rays'}]",['1 spectrum'],['ASCII']
+10.26302/sshade/experiment_ak_20141120_1,Mid-infrared attenuated total reflectance experiment with Ca2+ exchanged less 2 μm size fraction of montmorillonite (SAz-2) equilibrated with D2O vapor under variable relative humidity,SSHADE/LSD (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2022-11-04T08:20:29.000Z,2022-11-04T08:20:30.000Z,inist.sshade,mgeg,"natural terrestrial,phyllosilicate,Ca-exchanged beidellite SbCa-1 size-fraction &lt;1 µm,liquid,D2O 99.9 Sigma-Aldrich,laboratory measurement,ATReflection,macroscopic,MIR,Mid-Infrared,corrected ATR absorbance","[{'subject': 'natural terrestrial'}, {'subject': 'phyllosilicate'}, {'subject': 'Ca-exchanged beidellite SbCa-1 size-fraction &lt;1 µm'}, {'subject': 'liquid'}, {'subject': 'D2O 99.9 Sigma-Aldrich'}, {'subject': 'laboratory measurement'}, {'subject': 'ATReflection'}, {'subject': 'macroscopic'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'corrected ATR absorbance'}]",['3 spectra'],['ASCII']
+10.26302/sshade/experiment_rc_20191124_000,VIS-NIR reflectance spectra collected during low-temperature and near-vacuum sublimation of compact slabs of salty ice produced by slowly freezing solutions of Na2SO4 with three different concentrations,SSHADE/BYPASS (OSUG Data Center),2023.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",Compact slabs of salty (Na2SO4) ice are produced by slowly freezing small volumes of salt solutions into a laboratory freezer at 230K. The samples are then introduced in the SCITEAS-2 simulations chamber and their slow sublimation at low temperature and in secondary vacuum is followed for several tens of hours by VIS-NIR hyperspectral imaging.,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-06-09T17:17:05.000Z,2023-06-09T17:17:06.000Z,inist.sshade,mgeg,"laboratory measurement,biconical reflection,imaging,Vis,Visible,NIR,Near-Infrared,reflectance factor,water ice,Sodium sulfate hydrates,laboratory,inorganic molecular solid,sulfate","[{'subject': 'laboratory measurement', 'subjectScheme': 'main'}, {'subject': 'biconical reflection', 'subjectScheme': 'main'}, {'subject': 'imaging', 'subjectScheme': 'main'}, {'subject': 'Vis', 'subjectScheme': 'variables'}, {'subject': 'Visible', 'subjectScheme': 'variables'}, {'subject': 'NIR', 'subjectScheme': 'variables'}, {'subject': 'Near-Infrared', 'subjectScheme': 'variables'}, {'subject': 'reflectance factor', 'subjectScheme': 'variables'}, {'subject': 'water ice', 'subjectScheme': 'name'}, {'subject': 'Sodium sulfate hydrates', 'subjectScheme': 'name'}, {'subject': 'laboratory', 'subjectScheme': 'origin'}, {'subject': 'inorganic molecular solid', 'subjectScheme': 'compound type'}, {'subject': 'sulfate', 'subjectScheme': 'compound type'}]",['240 spectra'],['ASCII']
+10.5281/zenodo.10674398,easystats/performance: performance 0.10.9,Zenodo,2024.0,,Software,Creative Commons Attribution 4.0 International,"Changes
+
+
+
+
+r2() for models of class glmmTMB without random effects now returns the
+correct r-squared value for non-mixed models.
+
+
+
+check_itemscale() now also accepts data frames as input. In this case,
+factor_index must be specified, which must be a numeric vector of same
+length as number of columns in x, where each element is the index of the
+factor to which the respective column in x.
+
+
+
+check_itemscale() gets a print_html() method.
+
+
+
+Clarification in the documentation of the estimator argument for
+performance_aic().
+
+
+
+Improved plots for overdispersion-checks for negative-binomial models from
+package glmmTMB (affects check_overdispersion() and check_mnodel()).
+
+
+
+Improved detection rates for singularity in check_singularity() for models
+from package glmmTMB.
+
+
+
+For model of class glmmTMB, deviance residuals are now used in the
+check_model() plot.
+
+
+
+Improved (better to understand) error messages for check_model(),
+check_collinearity() and check_outliers() for models with non-numeric
+response variables.
+
+
+
+r2_kullback() now gives an informative error for non-supported models.
+
+
+
+Bug fixes
+
+
+
+
+Fixed issue in binned_residuals() for models with binary outcome, where
+in rare occasions empty bins could occur.
+
+
+
+performance_score() should no longer fail for models where scoring rules
+can't be calculated. Instead, an informative message is returned.
+
+
+
+check_outliers() now properly accept the percentage_central argument when
+using the ""mcd"" method.
+
+
+
+Fixed edge cases in check_collinearity() and check_outliers() for models
+with response variables of classes Date, POSIXct, POSIXlt or difftime.
+
+
+
+Fixed issue with check_model() for models of package quantreg.",api,True,findable,0.0,0.0,0.0,1.0,0.0,2024-02-17T18:09:47.000Z,2024-02-17T18:09:47.000Z,cern.zenodo,cern,,,,
+10.5281/zenodo.10485585,"Fig. 7 in The chloroplast membrane associated ceQORH putative quinone oxidoreductase reduces long-chain, stress-related oxidized lipids",Zenodo,2016.0,,Image,License Not Specified,"Fig. 7. Enzymatically derived RES oxylipins produced in the chloroplast that are reduced (green box) and not reduced by ceQORH (red boxes). The yellow box indicates the ceQORH reduction products. ceQORH reduces traumatin in vitro but with very low efficiency compared to AtAER (see text). As traumatin is produced on the cytosolic side of the chloroplast and AtAER is cytosolic we considered ceQORH activity on traumatin as non physiological. 13(S)-HPOD: (9Z,11E,13S)-13-hydroperoxy-octadecadienoic acid; 13 (S)-HPOT: (9Z,11E,13S,15Z)-13-hydroperoxy-octadecatrienoic acid; 12, 13-EOD: 12,13-epoxyoctadecadienoic acid; 12,13-EOT: 12,13-epoxyoctadecatrienoic acid.",api,True,findable,0.0,0.0,0.0,0.0,0.0,2024-01-11T04:59:51.000Z,2024-01-11T04:59:51.000Z,cern.zenodo,cern,"Biodiversity,Taxonomy","[{'subject': 'Biodiversity'}, {'subject': 'Taxonomy'}]",,
+10.26302/sshade/experiment_dt_20170706_005,Fe K edge XAS transmission of natural goethite FeO(OH) at ambient conditions,SSHADE/FAME (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2019-11-15T20:30:15.000Z,2019-11-15T20:30:16.000Z,inist.sshade,mgeg,"solid,commercial,non-oxide ceramic,BN powder,natural terrestrial,oxide-hydroxide,Natural goethite,laboratory measurement,transmission,None,hard X,hard X-rays","[{'subject': 'solid'}, {'subject': 'commercial'}, {'subject': 'non-oxide ceramic'}, {'subject': 'BN powder'}, {'subject': 'natural terrestrial'}, {'subject': 'oxide-hydroxide'}, {'subject': 'Natural goethite'}, {'subject': 'laboratory measurement'}, {'subject': 'transmission'}, {'subject': 'None'}, {'subject': 'hard X'}, {'subject': 'hard X-rays'}]",['1 spectrum'],['ASCII']
+10.6084/m9.figshare.22877643,Additional file 1 of Digital undergraduate medical education and patient and carer involvement: a rapid systematic review of current practice,figshare,2023.0,,Text,Creative Commons Attribution 4.0 International,Additional file 1. Sample Search Strategy (Ovid MEDLINE).,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-05-17T03:24:26.000Z,2023-05-17T03:24:27.000Z,figshare.ars,otjm,"Medicine,Science Policy,69999 Biological Sciences not elsewhere classified,FOS: Biological sciences,111714 Mental Health,FOS: Health sciences","[{'subject': 'Medicine'}, {'subject': 'Science Policy'}, {'subject': '69999 Biological Sciences not elsewhere classified', 'schemeUri': 'http://www.abs.gov.au/ausstats/abs@.nsf/0/6BB427AB9696C225CA2574180004463E', 'subjectScheme': 'FOR'}, {'subject': 'FOS: Biological sciences', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': '111714 Mental Health', 'schemeUri': 'http://www.abs.gov.au/ausstats/abs@.nsf/0/6BB427AB9696C225CA2574180004463E', 'subjectScheme': 'FOR'}, {'subject': 'FOS: Health sciences', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}]",['14508 Bytes'],
+10.26302/sshade/experiment_ak_20141116_1,Mid-infrared attenuated total reflectance experiment with Mg2+ exchanged less 0.1 μm size fraction of beidellite (SbId-1) equilibrated with D2O vapor under variable relative humidity,SSHADE/LSD (OSUG Data Center),2019.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2022-11-04T08:25:37.000Z,2022-11-04T08:25:38.000Z,inist.sshade,mgeg,"natural terrestrial,phyllosilicate,Mg-exchanged beidellite SbId-1 size-fraction &lt;0.1 µm,liquid,D2O 99.9 Sigma-Aldrich,laboratory measurement,ATReflection,macroscopic,MIR,Mid-Infrared,corrected ATR absorbance","[{'subject': 'natural terrestrial'}, {'subject': 'phyllosilicate'}, {'subject': 'Mg-exchanged beidellite SbId-1 size-fraction &lt;0.1 µm'}, {'subject': 'liquid'}, {'subject': 'D2O 99.9 Sigma-Aldrich'}, {'subject': 'laboratory measurement'}, {'subject': 'ATReflection'}, {'subject': 'macroscopic'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'corrected ATR absorbance'}]",['5 spectra'],['ASCII']
+10.5281/zenodo.10621171,easystats/insight: insight 0.19.8,Zenodo,2024.0,,Software,Creative Commons Attribution 4.0 International,"General
+
+
+
+
+Removed deprecated arguments in get_data.mmrm().
+
+
+
+Improved support for models of class rqs (package quantreg).
+
+
+
+Revised test to address forthcoming changes in the pscl package.
+
+
+
+Bug fixes
+
+
+
+
+Fixed issue in get_loglikelihood() for glm-models with binary outcome, where
+levels were defined in reversed order.
+
+
+
+Fixed issue in find_formula() for models of class glmmPQL (package MASS).
+
+
+
+Fixed issue in find_formula() for models of class gam (package mgcv) for
+the ""gaulss"" family.
+
+
+
+Fixed issue in get_variance() for glmmTMB models with family = ""ordbeta"".
+
+
+
+Fixed issue in model_info() with correctly detecting multivariate vgam/vglm
+models.",api,True,findable,0.0,0.0,0.0,1.0,0.0,2024-02-05T19:50:10.000Z,2024-02-05T19:50:10.000Z,cern.zenodo,cern,,,,
+10.26302/sshade/experiment_jr_20150621_001,W L3 edge XAS transmission of Tungsten oxydation in biological media,SSHADE/FAME (OSUG Data Center),2022.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2022-10-28T13:55:16.000Z,2022-10-28T13:55:17.000Z,inist.sshade,mgeg,"solid,commercial,non-oxide ceramic,BN powder,metal,W_metal,tungstate,WO3,oxide,WO2,laboratory measurement,fluorescence emission,None,hard X,hard X-rays","[{'subject': 'solid'}, {'subject': 'commercial'}, {'subject': 'non-oxide ceramic'}, {'subject': 'BN powder'}, {'subject': 'metal'}, {'subject': 'W_metal'}, {'subject': 'tungstate'}, {'subject': 'WO3'}, {'subject': 'oxide'}, {'subject': 'WO2'}, {'subject': 'laboratory measurement'}, {'subject': 'fluorescence emission'}, {'subject': 'None'}, {'subject': 'hard X'}, {'subject': 'hard X-rays'}]",['3 spectra'],['ASCII']
+10.26302/sshade/experiment_gm_20190905_001,Raman spectra of some oxide-hydroxide minerals,SSHADE/REAP (OSUG Data Center),2019.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,1.0,0.0,2021-05-13T07:46:33.000Z,2021-05-13T07:46:35.000Z,inist.sshade,mgeg,"laboratory measurement,Raman scattering,microscopy,MIR,Mid-Infrared,FIR,Far-Infrared,normalized Raman scattering intensity,Corundum,Hematite,Magnetite,Rutile,Anatase,Goethite,Geikielite,Romanechite,Brucite,natural terrestrial,oxide-hydroxide","[{'subject': 'laboratory measurement', 'subjectScheme': 'main'}, {'subject': 'Raman scattering', 'subjectScheme': 'main'}, {'subject': 'microscopy', 'subjectScheme': 'main'}, {'subject': 'MIR', 'subjectScheme': 'variables'}, {'subject': 'Mid-Infrared', 'subjectScheme': 'variables'}, {'subject': 'FIR', 'subjectScheme': 'variables'}, {'subject': 'Far-Infrared', 'subjectScheme': 'variables'}, {'subject': 'normalized Raman scattering intensity', 'subjectScheme': 'variables'}, {'subject': 'Corundum', 'subjectScheme': 'name'}, {'subject': 'Hematite', 'subjectScheme': 'name'}, {'subject': 'Magnetite', 'subjectScheme': 'name'}, {'subject': 'Rutile', 'subjectScheme': 'name'}, {'subject': 'Anatase', 'subjectScheme': 'name'}, {'subject': 'Goethite', 'subjectScheme': 'name'}, {'subject': 'Geikielite', 'subjectScheme': 'name'}, {'subject': 'Romanechite', 'subjectScheme': 'name'}, {'subject': 'Brucite', 'subjectScheme': 'name'}, {'subject': 'natural terrestrial', 'subjectScheme': 'origin'}, {'subject': 'oxide-hydroxide', 'subjectScheme': 'compound type'}]",['9 spectra'],['ASCII']
+10.26302/sshade/experiment_dt_20180117_005,Nb K edge XAS transmission of Nb metallic foil reference at ambient conditions,SSHADE/FAME (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2019-11-16T07:52:54.000Z,2019-11-16T07:52:55.000Z,inist.sshade,mgeg,"commercial,elemental solid,metallic Nb,laboratory measurement,transmission,None,hard X,hard X-rays","[{'subject': 'commercial'}, {'subject': 'elemental solid'}, {'subject': 'metallic Nb'}, {'subject': 'laboratory measurement'}, {'subject': 'transmission'}, {'subject': 'None'}, {'subject': 'hard X'}, {'subject': 'hard X-rays'}]",['1 spectrum'],['ASCII']
+10.26302/sshade/experiment_ik_20210602_001,Mo K edge XAS transmission of Na2MoO4 reference for energy resolution optimisation,SSHADE/FAME (OSUG Data Center),2021.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2021-06-09T06:57:34.000Z,2021-06-09T06:57:35.000Z,inist.sshade,mgeg,"solid,commercial,non-oxide ceramic,BN powder,molybdate,Na2MoO4,laboratory measurement,transmission,None,hard X","[{'subject': 'solid'}, {'subject': 'commercial'}, {'subject': 'non-oxide ceramic'}, {'subject': 'BN powder'}, {'subject': 'molybdate'}, {'subject': 'Na2MoO4'}, {'subject': 'laboratory measurement'}, {'subject': 'transmission'}, {'subject': 'None'}, {'subject': 'hard X'}]",['1 spectrum'],['ASCII']
+10.26302/sshade/experiment_bs_20121218_001,simulated NIR bidirectional reflection spectra (i=0-70°/e=0-70°/az=180°) of Na-Montmorillonite SWy-1 (20 µm grains) at 293K,SSHADE/GhoSST (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",simulated NIR bidirectional reflection spectra (i=0-70°/e=0-70°/az=180°) of Na-Montmorillonite SWy-1 (20µm grains) at 293K,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2019-12-29T08:49:25.000Z,2019-12-29T08:49:26.000Z,inist.sshade,mgeg,"simulated,phyllosilicate,Na-Montmorillonite,physically adsorbed phase,Adsorbed water,interlayer phase,Interlayer water,tektosilicate,Quartz,Plagioclase,sulfate,Gypsum,carbonate,Calcite,Dolomite,Kaolinite,Chlorites,inosilicate,Clinopyroxenes,Orthopyroxenes,numerical modeling,bidirectional reflection,macroscopic,NIR,Near-Infrared,reflectance factor","[{'subject': 'simulated'}, {'subject': 'phyllosilicate'}, {'subject': 'Na-Montmorillonite'}, {'subject': 'physically adsorbed phase'}, {'subject': 'Adsorbed water'}, {'subject': 'interlayer phase'}, {'subject': 'Interlayer water'}, {'subject': 'tektosilicate'}, {'subject': 'Quartz'}, {'subject': 'Plagioclase'}, {'subject': 'sulfate'}, {'subject': 'Gypsum'}, {'subject': 'carbonate'}, {'subject': 'Calcite'}, {'subject': 'Dolomite'}, {'subject': 'Kaolinite'}, {'subject': 'Chlorites'}, {'subject': 'inosilicate'}, {'subject': 'Clinopyroxenes'}, {'subject': 'Orthopyroxenes'}, {'subject': 'numerical modeling'}, {'subject': 'bidirectional reflection'}, {'subject': 'macroscopic'}, {'subject': 'NIR'}, {'subject': 'Near-Infrared'}, {'subject': 'reflectance factor'}]",['1 spectrum'],['ASCII']
+10.26302/sshade/experiment_lb_20200226_001,"UV Raman spectra (λ = 244 nm) of chondritic IOM (CI, CM, CR, ung.)",SSHADE/GhoSST (OSUG Data Center),2020.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2020-06-02T14:50:19.000Z,2020-06-02T14:50:20.000Z,inist.sshade,mgeg,"extraterrestrial,organic molecular solid,IOM HF/HCl of Alais,IOM HF/HCl of Cold Bokkeveld,IOM HF/HCl of Murchison,IOM HF/HCl of Murray,IOM HF/HCl of Orgueil,IOM HF/HCl of Renazzo,IOM HF/HCl of Tagish Lake,laboratory measurement,Raman scattering,microscopy,MIR,Mid-Infrared,Raman scattering intensity,normalized Raman scattering intensity","[{'subject': 'extraterrestrial'}, {'subject': 'organic molecular solid'}, {'subject': 'IOM HF/HCl of Alais'}, {'subject': 'IOM HF/HCl of Cold Bokkeveld'}, {'subject': 'IOM HF/HCl of Murchison'}, {'subject': 'IOM HF/HCl of Murray'}, {'subject': 'IOM HF/HCl of Orgueil'}, {'subject': 'IOM HF/HCl of Renazzo'}, {'subject': 'IOM HF/HCl of Tagish Lake'}, {'subject': 'laboratory measurement'}, {'subject': 'Raman scattering'}, {'subject': 'microscopy'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'Raman scattering intensity'}, {'subject': 'normalized Raman scattering intensity'}]",['14 spectra'],['ASCII']
+10.5281/zenodo.10656089,Takin 2,Zenodo,2023.0,en,Software,Other (Open),"This is Takin 2, an inelastic neutron scattering software suite.
+
+The source code repository is available here:https://github.com/ILLGrenoble/takin, https://github.com/t-weber/takin2.
+
+The software documentation is available here:https://github.com/ILLGrenoble/takin/wiki.
+
+Note: This is version 2 of the software; Takin version 1 (2014-2019) is available here: https://github.com/t-weber/takin and has the DOI 10.5281/zenodo.3961491.
+
+ ",api,True,findable,0.0,0.0,1.0,1.0,0.0,2024-02-14T04:36:31.000Z,2024-02-14T04:36:31.000Z,cern.zenodo,cern,"neutron scattering,triple-axis spectrometer,resolution convolution fitting,linear spin-waves,magnons,spurion calculation","[{'subject': 'neutron scattering'}, {'subject': 'triple-axis spectrometer'}, {'subject': 'resolution convolution fitting'}, {'subject': 'linear spin-waves'}, {'subject': 'magnons'}, {'subject': 'spurion calculation'}]",,
+10.5281/zenodo.10370097,"Data from ""Elevation affects both the occurrence of ungulate browsing and its effect on tree seedling growth for four major tree species in European mountain forests""",Zenodo,2023.0,,Dataset,Creative Commons Attribution 4.0 International,"This repository contains the field data used in the paper from Bernard et al. on the interactive effect of elevation and ungulate browsing on tree regeneration. This dataset is associated with a github repository containing the code to run the analyses of the paper, publicly available at https://github.com/jbarrere3/BaccaraPaper. 
+ 
+Data were collected for the Baccara project, by Elena Granda, Raquel Benavides, Sonia Rabasa, Georges Kunstler, and Marco Heurich. ",api,True,findable,0.0,0.0,0.0,0.0,0.0,2023-12-13T09:18:53.000Z,2023-12-13T09:18:54.000Z,cern.zenodo,cern,,,,
+10.26302/sshade/experiment_eb_20180618_001,U L3 edge XAS HERFD of U(IV)-uraninite and U(VI)-uranyl references,SSHADE/FAME (OSUG Data Center),2022.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",Varying the uranium speciation.,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2022-03-10T12:46:33.000Z,2022-03-10T12:46:34.000Z,inist.sshade,mgeg,"laboratory,oxide,UO2,liquid solution,U(VI)-uranyl solution,laboratory measurement,fluorescence emission,None,hard X,hard X-rays","[{'subject': 'laboratory'}, {'subject': 'oxide'}, {'subject': 'UO2'}, {'subject': 'liquid solution'}, {'subject': 'U(VI)-uranyl solution'}, {'subject': 'laboratory measurement'}, {'subject': 'fluorescence emission'}, {'subject': 'None'}, {'subject': 'hard X'}, {'subject': 'hard X-rays'}]",['2 spectra'],['ASCII']
+10.26302/sshade/experiment_lb_20170731_005,Mid-IR absorbance spectra of Renazzo matrix grains under vacuum at different temperatures,SSHADE/GhoSST (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","Raw, normalized and baseline-corrected Mid-IR spectra of several matrix grains of RENAZZO (pressed on diamond) under vacuum at ambient temperature and 300°C",mds,True,findable,0.0,0.0,0.0,1.0,0.0,2020-02-11T11:54:57.000Z,2020-02-11T11:54:58.000Z,inist.sshade,mgeg,"extraterrestrial,complex organic-mineral mix,matrix RENAZZO,physically adsorbed phase,adsorbed water,matrix RENAZZO heated at 300°C,laboratory measurement,transmission,microscopy,MIR,Mid-Infrared,absorbance,normalized absorbance","[{'subject': 'extraterrestrial'}, {'subject': 'complex organic-mineral mix'}, {'subject': 'matrix RENAZZO'}, {'subject': 'physically adsorbed phase'}, {'subject': 'adsorbed water'}, {'subject': 'matrix RENAZZO heated at 300°C'}, {'subject': 'laboratory measurement'}, {'subject': 'transmission'}, {'subject': 'microscopy'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'absorbance'}, {'subject': 'normalized absorbance'}]",['20 spectra'],['ASCII']
+10.6084/m9.figshare.24202753,Additional file 3 of Obstructive sleep apnea: a major risk factor for COVID-19 encephalopathy?,figshare,2023.0,,Text,Creative Commons Attribution 4.0 International,Additional file 3: Supplemental Table 3. Cerebrospinal fluid analyses at the time of COVID-19 acute encephalopathy.,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-09-27T03:26:11.000Z,2023-09-27T03:26:12.000Z,figshare.ars,otjm,"Biophysics,Medicine,Cell Biology,Neuroscience,Physiology,FOS: Biological sciences,Pharmacology,Biotechnology,Sociology,FOS: Sociology,Immunology,FOS: Clinical medicine,Cancer,Mental Health,Virology","[{'subject': 'Biophysics'}, {'subject': 'Medicine'}, {'subject': 'Cell Biology'}, {'subject': 'Neuroscience'}, {'subject': 'Physiology'}, {'subject': 'FOS: Biological sciences', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': 'Pharmacology'}, {'subject': 'Biotechnology'}, {'subject': 'Sociology'}, {'subject': 'FOS: Sociology', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': 'Immunology'}, {'subject': 'FOS: Clinical medicine', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': 'Cancer'}, {'subject': 'Mental Health'}, {'subject': 'Virology'}]",['19116 Bytes'],
+10.15778/resif.3a2008,ARC Vanutu temporay experiment (RESIF-SISMOB),RESIF - Réseau Sismologique et géodésique Français,2011.0,en,Dataset,"Open Access,Creative Commons Attribution 4.0 International","Local network in central Vanuatu (south Santo and north Mallicolo), covering the seismogenic zone in the regions where several asperities enter into subduction",mds,True,findable,0.0,0.0,0.0,3.0,0.0,2018-02-21T08:51:06.000Z,2018-02-21T08:51:06.000Z,inist.resif,vcob,"Seismology,Geodynamics","[{'subject': 'Seismology'}, {'subject': 'Geodynamics'}]",['510 Gb;89 stations'],"['stationXML metadata', 'miniseed data']"
+10.26302/sshade/experiment_tg_20180503_001,Vis-VNIR optical indices of 4 Tholins films,SSHADE/SPAN (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","Set of Visible-Very Near IR optical indices of tholins films formed with different $CH_4$ percentages in $N_2$ gas: 1%, 2%, 5%, 10%",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-05-09T12:44:13.000Z,2023-05-09T12:44:14.000Z,inist.sshade,mgeg,"laboratory measurement,ellipsometry,macroscopic,Vis,Visible,optical constants,Tholins,Tholins LATMOS Film 90%N2:10%CH4,Tholins LATMOS Film 99%N2:1%CH4,Tholins LATMOS Film 98%N2:2%CH4,laboratory,complex macromolecular mixture","[{'subject': 'laboratory measurement', 'subjectScheme': 'main'}, {'subject': 'ellipsometry', 'subjectScheme': 'main'}, {'subject': 'macroscopic', 'subjectScheme': 'main'}, {'subject': 'Vis', 'subjectScheme': 'variables'}, {'subject': 'Visible', 'subjectScheme': 'variables'}, {'subject': 'optical constants', 'subjectScheme': 'variables'}, {'subject': 'Tholins', 'subjectScheme': 'name'}, {'subject': 'Tholins LATMOS Film 90%N2:10%CH4', 'subjectScheme': 'name'}, {'subject': 'Tholins LATMOS Film 99%N2:1%CH4', 'subjectScheme': 'name'}, {'subject': 'Tholins LATMOS Film 98%N2:2%CH4', 'subjectScheme': 'name'}, {'subject': 'laboratory', 'subjectScheme': 'origin'}, {'subject': 'complex macromolecular mixture', 'subjectScheme': 'compound type'}]",['4 spectra'],['ASCII']
+10.26302/sshade/experiment_bs_20200202_001,"MIR absorption coefficient spectra of H2S (nu_1,nu_3 bands) in 3 different phases (amorphous, III, II) and diluted in SO2 ice",SSHADE/GhoSST (OSUG Data Center),2020.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","MIR absorption coefficient spectra of H2S (around the nu_1,nu_3 bands) in 3 different phases (amorphous (56K), III (85K), II (107K)) and diluted in SO2 ice (130K)",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2020-04-20T17:28:05.000Z,2020-04-20T17:28:05.000Z,inist.sshade,mgeg,"laboratory,inorganic molecular solid,H2S amorphous,H2S phase III,H2S phase II,solid molecular mixture,crystalline SO2:CO2:H2S=92.5%:4.7%:2.8% ice mixture,laboratory measurement,transmission,macroscopic,MIR,Mid-Infrared,absorption coefficient","[{'subject': 'laboratory'}, {'subject': 'inorganic molecular solid'}, {'subject': 'H2S amorphous'}, {'subject': 'H2S phase III'}, {'subject': 'H2S phase II'}, {'subject': 'solid molecular mixture'}, {'subject': 'crystalline SO2:CO2:H2S=92.5%:4.7%:2.8% ice mixture'}, {'subject': 'laboratory measurement'}, {'subject': 'transmission'}, {'subject': 'macroscopic'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'absorption coefficient'}]",['4 spectra'],['ASCII']
+10.26302/sshade/experiment_lb_20171025_001,Baseline-corrected and normalized Mid-IR absorbance spectra of fragments of AMMs pressed on diamond or germanium window under vacuum and at 80°C,SSHADE/GhoSST (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","MIR spectra of several fragments of Fg-AMMs DC06-09 (vacuum, 80°C) pressed on diamond or germanium substrate",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2020-02-11T11:13:50.000Z,2020-02-11T11:13:50.000Z,inist.sshade,mgeg,"extraterrestrial,complex organic-mineral mix,organic-minerals mixture,physically adsorbed phase,adsorbed water,laboratory measurement,transmission,microscopy,MIR,Mid-Infrared,normalized absorbance,absorbance","[{'subject': 'extraterrestrial'}, {'subject': 'complex organic-mineral mix'}, {'subject': 'organic-minerals mixture'}, {'subject': 'physically adsorbed phase'}, {'subject': 'adsorbed water'}, {'subject': 'laboratory measurement'}, {'subject': 'transmission'}, {'subject': 'microscopy'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'normalized absorbance'}, {'subject': 'absorbance'}]",['11 spectra'],['ASCII']
+10.26302/sshade/experiment_cl_20181123_001,Pt L3 edge XAS HERFD of metallic Pt powder at ambient conditions,SSHADE/FAME (OSUG Data Center),2020.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2020-04-15T07:43:23.000Z,2020-04-15T07:43:23.000Z,inist.sshade,mgeg,"solid,commercial,non-oxide ceramic,BN powder,elemental solid,metallic Pt,laboratory measurement,fluorescence emission,None,hard X","[{'subject': 'solid'}, {'subject': 'commercial'}, {'subject': 'non-oxide ceramic'}, {'subject': 'BN powder'}, {'subject': 'elemental solid'}, {'subject': 'metallic Pt'}, {'subject': 'laboratory measurement'}, {'subject': 'fluorescence emission'}, {'subject': 'None'}, {'subject': 'hard X'}]",['1 spectrum'],['ASCII']
+10.26302/sshade/experiment_mc_20181026_1,"Vis-IR spectroscopy of mixtures including water ice, kerite, and pyrrhotite",SSHADE/REFL_SLAB (OSUG Data Center),2021.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","We measured the Vis-IR spectral reflectance of mixtures including water ice, kerite, and pyrrhotite, with varying abundances, mixing modality, and grain size",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2021-11-02T09:16:14.000Z,2021-11-02T09:16:15.000Z,inist.sshade,mgeg,"solid,laboratory,inorganic molecular solid,water ice,carbonaceous,natural terrestrial,complex macromolecular mixture,Low kerite (albertite) PAM#42,sulfide,Pyrrhotite (iron_sulfide),laboratory measurement,bidirectional reflection,macroscopic,Vis,Visible,NIR,Near-Infrared,reflectance factor","[{'subject': 'solid'}, {'subject': 'laboratory'}, {'subject': 'inorganic molecular solid'}, {'subject': 'water ice'}, {'subject': 'carbonaceous'}, {'subject': 'natural terrestrial'}, {'subject': 'complex macromolecular mixture'}, {'subject': 'Low kerite (albertite) PAM#42'}, {'subject': 'sulfide'}, {'subject': 'Pyrrhotite (iron_sulfide)'}, {'subject': 'laboratory measurement'}, {'subject': 'bidirectional reflection'}, {'subject': 'macroscopic'}, {'subject': 'Vis'}, {'subject': 'Visible'}, {'subject': 'NIR'}, {'subject': 'Near-Infrared'}, {'subject': 'reflectance factor'}]",['17 spectra'],['ASCII']
+10.26302/sshade/experiment_bs_20120924_011,NIR Optical constants spectrum of H2O Ih crystal and H2O liquid from 20 to 293 K,SSHADE/GhoSST (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2020-12-22T21:20:11.000Z,2020-12-22T21:20:12.000Z,inist.sshade,mgeg,"laboratory,liquid,H2O liquid,inorganic molecular solid,H2O crystalline - phase Ih,laboratory measurement,transmission,macroscopic,NIR,Near-Infrared,optical constants","[{'subject': 'laboratory'}, {'subject': 'liquid'}, {'subject': 'H2O liquid'}, {'subject': 'inorganic molecular solid'}, {'subject': 'H2O crystalline - phase Ih'}, {'subject': 'laboratory measurement'}, {'subject': 'transmission'}, {'subject': 'macroscopic'}, {'subject': 'NIR'}, {'subject': 'Near-Infrared'}, {'subject': 'optical constants'}]",['28 spectra'],['ASCII']
+10.6084/m9.figshare.24647123,Additional file 1 of Effects of a physical activity and endometriosis-based education program delivered by videoconference on endometriosis symptoms: the CRESCENDO program (inCRease physical Exercise and Sport to Combat ENDOmetriosis) protocol study,figshare,2023.0,,Text,Creative Commons Attribution 4.0 International,Additional file 1. Randomization script,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-11-28T04:40:37.000Z,2023-11-28T04:40:37.000Z,figshare.ars,otjm,"Medicine,Genetics,FOS: Biological sciences,Physiology,Science Policy,Sociology,FOS: Sociology,Biological Sciences not elsewhere classified","[{'subject': 'Medicine'}, {'subject': 'Genetics'}, {'subject': 'FOS: Biological sciences', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': 'Physiology'}, {'subject': 'Science Policy'}, {'subject': 'Sociology'}, {'subject': 'FOS: Sociology', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': 'Biological Sciences not elsewhere classified'}]",['12261 Bytes'],
+10.26302/sshade/bandlist_abs_co2_co2-i,Absorption band list of CO2 in natural solid CO2 (phase I),SSHADE/BANDLIST (OSUG Data Center),2021.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",FIR-MIR-NIR-VUV absorption band list of the isotopes of $CO_2$ in natural solid $CO_2$ (phase I),mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-04-21T07:10:59.000Z,2023-04-21T07:10:59.000Z,inist.sshade,mgeg,"natural CO2 - phase I,Carbon dioxide,Carbon dioxide ice,Cubic CO2-I ice,Carbon dioxide,124-38-9,CO2,non polar molecular solid,molecular solids with apolar molecules,inorganic molecular solid,absorption,FIR,MIR,NIR,VUV,band frequency,band width,band intensity,transition and vibration modes","[{'subject': 'natural CO2 - phase I', 'subjectScheme': 'name'}, {'subject': 'Carbon dioxide', 'subjectScheme': 'name'}, {'subject': 'Carbon dioxide ice', 'subjectScheme': 'name'}, {'subject': 'Cubic CO2-I ice', 'subjectScheme': 'name'}, {'subject': 'Carbon dioxide', 'subjectScheme': 'IUPAC name'}, {'subject': '124-38-9', 'subjectScheme': 'CAS number'}, {'subject': 'CO2', 'subjectScheme': 'formula'}, {'subject': 'non polar molecular solid', 'subjectScheme': 'class'}, {'subject': 'molecular solids with apolar molecules', 'subjectScheme': 'class'}, {'subject': 'inorganic molecular solid', 'subjectScheme': 'compound type'}, {'subject': 'absorption', 'subjectScheme': 'var'}, {'subject': 'FIR', 'subjectScheme': 'var'}, {'subject': 'MIR', 'subjectScheme': 'var'}, {'subject': 'NIR', 'subjectScheme': 'var'}, {'subject': 'VUV', 'subjectScheme': 'var'}, {'subject': 'band frequency', 'subjectScheme': 'var'}, {'subject': 'band width', 'subjectScheme': 'var'}, {'subject': 'band intensity', 'subjectScheme': 'var'}, {'subject': 'transition and vibration modes', 'subjectScheme': 'var'}]",,['ASCII']
+10.15778/resif.8f2016,"MARGATS temporary experiment, French Guiana (RESIF-SISMOB)",RESIF - Réseau Sismologique et géodésique Français,2017.0,,Dataset,,"Study of the origin and formation of the Demerara plateau. 13 broad-band stations in French Guyana, near the border with Surinam.",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2022-03-17T15:56:43.000Z,2022-03-17T15:57:33.000Z,inist.resif,vcob,Margats,[{'subject': 'Margats'}],"['13 stations, 3.5Go (miniseed format)']","['Miniseed data', 'stationXML metadata']"
+10.26302/sshade/experiment_gs_20170705_001,Ag K edge XAS transmission of PVP-coated Ag nano-particles,SSHADE/FAME (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2019-11-16T08:15:59.000Z,2019-11-16T08:15:59.000Z,inist.sshade,mgeg,"solid,commercial,non-oxide ceramic,BN powder,elemental solid,Ag nanoparticle,homopolymer,PVP,laboratory measurement,transmission,None,hard X,hard X-rays","[{'subject': 'solid'}, {'subject': 'commercial'}, {'subject': 'non-oxide ceramic'}, {'subject': 'BN powder'}, {'subject': 'elemental solid'}, {'subject': 'Ag nanoparticle'}, {'subject': 'homopolymer'}, {'subject': 'PVP'}, {'subject': 'laboratory measurement'}, {'subject': 'transmission'}, {'subject': 'None'}, {'subject': 'hard X'}, {'subject': 'hard X-rays'}]",['1 spectrum'],['ASCII']
+10.26302/sshade/experiment_rc_20200109_000,VIS-NIR reflectance spectra collected during low-temperature and near-vacuum sublimation of compact slabs of salty ice produced by slowly freezing solutions of MgCl2 with three different concentrations,SSHADE/BYPASS (OSUG Data Center),2023.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",Compact slabs of salty (MgCl2) ice are produced by slowly freezing small volumes of salt solutions into a laboratory freezer at 230K. The samples are then introduced in the SCITEAS-2 simulations chamber and their slow sublimation at low temperature and in secondary vacuum is followed for several tens of hours by VIS-NIR hyperspectral imaging.,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-06-09T17:17:00.000Z,2023-06-09T17:17:01.000Z,inist.sshade,mgeg,"laboratory measurement,biconical reflection,imaging,Vis,Visible,NIR,Near-Infrared,reflectance factor,water ice,Magnesium(II) chloride hydrate,laboratory,inorganic molecular solid,chloride","[{'subject': 'laboratory measurement', 'subjectScheme': 'main'}, {'subject': 'biconical reflection', 'subjectScheme': 'main'}, {'subject': 'imaging', 'subjectScheme': 'main'}, {'subject': 'Vis', 'subjectScheme': 'variables'}, {'subject': 'Visible', 'subjectScheme': 'variables'}, {'subject': 'NIR', 'subjectScheme': 'variables'}, {'subject': 'Near-Infrared', 'subjectScheme': 'variables'}, {'subject': 'reflectance factor', 'subjectScheme': 'variables'}, {'subject': 'water ice', 'subjectScheme': 'name'}, {'subject': 'Magnesium(II) chloride hydrate', 'subjectScheme': 'name'}, {'subject': 'laboratory', 'subjectScheme': 'origin'}, {'subject': 'inorganic molecular solid', 'subjectScheme': 'compound type'}, {'subject': 'chloride', 'subjectScheme': 'compound type'}]",['284 spectra'],['ASCII']
+10.6084/m9.figshare.22625617,"Additional file 4 of A multicentre, patient- and assessor-blinded, non-inferiority, randomised and controlled phase II trial to compare standard and torque teno virus-guided immunosuppression in kidney transplant recipients in the first year after transplantation: TTVguideIT",figshare,2023.0,,Text,Creative Commons Attribution 4.0 International,Additional file 4.,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-04-13T18:56:25.000Z,2023-04-13T18:56:26.000Z,figshare.ars,otjm,"Immunology,FOS: Clinical medicine","[{'subject': 'Immunology'}, {'subject': 'FOS: Clinical medicine', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}]",['139801 Bytes'],
+10.6084/m9.figshare.22625620,"Additional file 5 of A multicentre, patient- and assessor-blinded, non-inferiority, randomised and controlled phase II trial to compare standard and torque teno virus-guided immunosuppression in kidney transplant recipients in the first year after transplantation: TTVguideIT",figshare,2023.0,,Text,Creative Commons Attribution 4.0 International,Additional file 5.,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-04-13T18:56:21.000Z,2023-04-13T18:56:21.000Z,figshare.ars,otjm,"Immunology,FOS: Clinical medicine","[{'subject': 'Immunology'}, {'subject': 'FOS: Clinical medicine', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}]",['182300 Bytes'],
+10.15778/resif.9c2019,"COPIACO temporary deployment around Copiapo, Chili (RESIF-SISMOB)",RESIF - Réseau Sismologique et géodésique Français,2023.0,,Dataset,,"Slow-slip events have recently been detected along the Chilean subduction in the Atacama region (Klein et al., GRL 2018). To monitor the seismicity associated with such events, we have deployed 3 broadband stations to complete the chilean network in the region. These stations will be on the field for three years (the end of the deployment is planed in 2022).",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2021-12-06T16:50:02.000Z,2021-12-06T16:53:51.000Z,inist.resif,vcob,"Seismology,Chilean subduction zone,Atacama","[{'subject': 'Seismology'}, {'subject': 'Chilean subduction zone'}, {'subject': 'Atacama'}]","['3 stations, 31Go (miniseed format)']","['Miniseed data', 'stationXML metadata']"
+10.6084/m9.figshare.22620040,"Additional file 4 of Biallelic variants in NOS3 and GUCY1A3, the two major genes of the nitric oxide pathway, cause moyamoya cerebral angiopathy",figshare,2023.0,,Text,Creative Commons Attribution 4.0 International,Additional file 4: NOS3 homozygous splice variant in M084 and NOS3 homozygous missense variant in M035.,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-04-13T14:39:30.000Z,2023-04-13T16:07:50.000Z,figshare.ars,otjm,"Genetics,FOS: Biological sciences","[{'subject': 'Genetics'}, {'subject': 'FOS: Biological sciences', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}]",['286190 Bytes'],
+10.5281/zenodo.10634157,Managing LimeSurvey Data Using R,Zenodo,2024.0,,Dataset,Creative Commons Attribution 4.0 International,"A template for managing LimeSurvey data using R.
+
+You will find:
+
+
+
+The dataset ""20240208_emap_LimeSurvey_R_data_file.csv""
+
+The .Rmd file containing the script ""RMarkdown_LimeSurvey_Template.Rmd""
+
+The .html file of the .Rmd file ""RMarkdown_LimeSurvey_Template.html""
+
+
+The dataset comes from the ""Promoting Physical Activity in People With Chronic Diseases: The Role of Affective Mechanisms"" project. ",api,True,findable,0.0,0.0,0.0,0.0,0.0,2024-02-12T08:57:53.000Z,2024-02-12T08:57:53.000Z,cern.zenodo,cern,"R,Markdown,Data Management,Open Science,LimeSurvey","[{'subject': 'R'}, {'subject': 'Markdown'}, {'subject': 'Data Management'}, {'subject': 'Open Science'}, {'subject': 'LimeSurvey'}]",,
+10.26302/sshade/experiment_vc_20050727_001,Vis-NIR reflectance spectra of Narbonne sand (NS 243) wetted with water and dried in ambiant air at 38°C,SSHADE/SSTONE (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","In order to investigate the spectral behavior of humidity on sand spectra, we have acquired laboratory reflectance spectra of a sand containing various proportion of water. Water was deposited on a dry sand (previously dried in an oven at 40°C during one night). During the experiment, the sample is then dried, under the sun at 38°C. A spectrum is acquired every 5 minutes with an ASD FieldSpec3FR. This experiment was done on Narbonne sand (NS 243)",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2021-05-19T19:16:05.000Z,2021-05-19T19:16:06.000Z,inist.sshade,mgeg,"mineral,natural terrestrial,phyllosilicate,Illite,Chlorite,liquid,Liquid water,laboratory measurement,bidirectional reflection,macroscopic,Vis,Visible,NIR,Near-Infrared,bidirectional reflectance","[{'subject': 'mineral'}, {'subject': 'natural terrestrial'}, {'subject': 'phyllosilicate'}, {'subject': 'Illite'}, {'subject': 'Chlorite'}, {'subject': 'liquid'}, {'subject': 'Liquid water'}, {'subject': 'laboratory measurement'}, {'subject': 'bidirectional reflection'}, {'subject': 'macroscopic'}, {'subject': 'Vis'}, {'subject': 'Visible'}, {'subject': 'NIR'}, {'subject': 'Near-Infrared'}, {'subject': 'bidirectional reflectance'}]",['29 spectra'],['ASCII']
+10.26302/sshade/experiment_bs_20200103_001,Near and Mid-IR optical constants of crystalline H2O ice Ih at 140-145K,SSHADE/GhoSST (OSUG Data Center),2020.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","Near and Mid-IR optical constants of crystalline H2O ice Ih at 140K (NIR) - 145K (MIR). The data are completed in the Visible and UV (&gt; 10500 $cm^{-1}$, &lt; 0.95 µm) with data at 270K from Warren (1986)",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2020-01-03T15:23:19.000Z,2020-01-03T15:23:19.000Z,inist.sshade,mgeg,"laboratory,inorganic molecular solid,H2O ice I,laboratory measurement,transmission,macroscopic,MIR,Mid-Infrared,NIR,Near-Infrared,optical constants","[{'subject': 'laboratory'}, {'subject': 'inorganic molecular solid'}, {'subject': 'H2O ice I'}, {'subject': 'laboratory measurement'}, {'subject': 'transmission'}, {'subject': 'macroscopic'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'NIR'}, {'subject': 'Near-Infrared'}, {'subject': 'optical constants'}]",['1 spectrum'],['ASCII']
+10.26302/sshade/experiment_dt_20171221_001,Au L3 edge XAS transmission of Au metallic foil reference at ambient conditions,SSHADE/FAME (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2019-11-15T20:30:55.000Z,2019-11-15T20:30:56.000Z,inist.sshade,mgeg,"commercial,elemental solid,metallic Au,laboratory measurement,transmission,None,hard X,hard X-rays","[{'subject': 'commercial'}, {'subject': 'elemental solid'}, {'subject': 'metallic Au'}, {'subject': 'laboratory measurement'}, {'subject': 'transmission'}, {'subject': 'None'}, {'subject': 'hard X'}, {'subject': 'hard X-rays'}]",['1 spectrum'],['ASCII']
+10.26302/sshade/experiment_op_20200908_001,"Vis-NIR reflectance spectra of powdered olivine, pyroxene, smectite and silica at 4 different grain sizes (from sub-µm to 200 µm) and with sub-µm grains in compact or porous surfaces",SSHADE/GhoSST (OSUG Data Center),2020.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","We measured the reflectance spectra (from 0.5 to 4.2 µm) of powders of olivine, pyroxene, a smectite-rich material, and amorphous silica. The powders were grinded and sieved and the spectra of four size fractions were measured: 100-200 µm, 50-100 µm, 0-50 µm, and sub-micrometer sized grains. In addition, porous surfaces of the latter grains were produced by mixing them with water ice and sublimating the ice.",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2020-10-06T07:47:58.000Z,2020-10-06T07:47:59.000Z,inist.sshade,mgeg,"mineral,laboratory,natural terrestrial,nesosilicate,Olivine Forsterite,tektosilicate,Quartz,inosilicate,Enstatite,Diopside,phyllosilicate,Talc,Albite,Calcium amphibole,Kaolinite,Smectite,Illite,Microcline,commercial,silicate,Silica amorphous,tectosilicate,laboratory measurement,bidirectional reflection,macroscopic,Vis,Visible,NIR,Near-Infrared,reflectance factor","[{'subject': 'mineral'}, {'subject': 'laboratory'}, {'subject': 'natural terrestrial'}, {'subject': 'nesosilicate'}, {'subject': 'Olivine Forsterite'}, {'subject': 'tektosilicate'}, {'subject': 'Quartz'}, {'subject': 'inosilicate'}, {'subject': 'Enstatite'}, {'subject': 'Diopside'}, {'subject': 'phyllosilicate'}, {'subject': 'Talc'}, {'subject': 'Albite'}, {'subject': 'Calcium amphibole'}, {'subject': 'Kaolinite'}, {'subject': 'Smectite'}, {'subject': 'Illite'}, {'subject': 'Microcline'}, {'subject': 'commercial'}, {'subject': 'silicate'}, {'subject': 'Silica amorphous'}, {'subject': 'tectosilicate'}, {'subject': 'laboratory measurement'}, {'subject': 'bidirectional reflection'}, {'subject': 'macroscopic'}, {'subject': 'Vis'}, {'subject': 'Visible'}, {'subject': 'NIR'}, {'subject': 'Near-Infrared'}, {'subject': 'reflectance factor'}]",['19 spectra'],['ASCII']
+10.26302/sshade/experiment_ak_20141102_1,Mid-infrared attenuated total reflectance experiment with Na+ exchanged less 1 μm size fraction of montmorillonite (SCa-3) equilibrated with H2O vapor under variable relative humidity,SSHADE/LSD (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2019-11-18T08:29:25.000Z,2019-11-18T08:29:26.000Z,inist.sshade,mgeg,"natural terrestrial,phyllosilicate,Na-exchanged montmorillonite SCa-3 size-fraction &lt;1 µm,liquid,H2O deionized,laboratory measurement,ATReflection,macroscopic,MIR,Mid-Infrared,corrected ATR absorbance","[{'subject': 'natural terrestrial'}, {'subject': 'phyllosilicate'}, {'subject': 'Na-exchanged montmorillonite SCa-3 size-fraction &lt;1 µm'}, {'subject': 'liquid'}, {'subject': 'H2O deionized'}, {'subject': 'laboratory measurement'}, {'subject': 'ATReflection'}, {'subject': 'macroscopic'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'corrected ATR absorbance'}]",['6 spectra'],['ASCII']
+10.26302/sshade/experiment_dt_20180117_003,Mn K edge XAS transmission of Mn metallic reference at ambient conditions,SSHADE/FAME (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2019-11-16T07:51:59.000Z,2019-11-16T07:52:00.000Z,inist.sshade,mgeg,"commercial,elemental solid,metallic Mn,laboratory measurement,transmission,None,hard X,hard X-rays","[{'subject': 'commercial'}, {'subject': 'elemental solid'}, {'subject': 'metallic Mn'}, {'subject': 'laboratory measurement'}, {'subject': 'transmission'}, {'subject': 'None'}, {'subject': 'hard X'}, {'subject': 'hard X-rays'}]",['1 spectrum'],['ASCII']
+10.26302/sshade/experiment_ak_20141121_1,Mid-infrared attenuated total reflectance experiment with Ca2+ exchanged less 2 μm size fraction of synthetic saponite equilibrated with D2O vapor under variable relative humidity,SSHADE/LSD (OSUG Data Center),2019.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2022-11-04T08:16:06.000Z,2022-11-04T08:16:07.000Z,inist.sshade,mgeg,"natural terrestrial,phyllosilicate,Ca-exchanged saponite SAP size-fraction &lt;2 µm,liquid,D2O 99.9 Sigma-Aldrich,laboratory measurement,ATReflection,macroscopic,MIR,Mid-Infrared,corrected ATR absorbance","[{'subject': 'natural terrestrial'}, {'subject': 'phyllosilicate'}, {'subject': 'Ca-exchanged saponite SAP size-fraction &lt;2 µm'}, {'subject': 'liquid'}, {'subject': 'D2O 99.9 Sigma-Aldrich'}, {'subject': 'laboratory measurement'}, {'subject': 'ATReflection'}, {'subject': 'macroscopic'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'corrected ATR absorbance'}]",['3 spectra'],['ASCII']
+10.26302/sshade/bandlist_raman_otavite,Raman bandlist of natural Otavite,SSHADE/BANDLIST (OSUG Data Center),2023.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",MIR-FIR Raman bandlist of natural Otavite at 295K,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-08-14T08:34:35.000Z,2023-08-14T08:34:36.000Z,inist.sshade,mgeg,"Otavite,Cadmium cation,Carbonate anion,Cadmium(2+) cation,22537-48-0,513-78-0,Cd2+,(CO3)2-,CdCO3,Otavite,non-silicate mineral,carbonate,carbonates, nitrates, borates,anhydrous carbonates,Calcite group (Trigonal: R-3c),14.01.01.07,05.AB.05,Raman scattering,FIR,MIR,band frequency,band width,band intensity,transition and vibration modes","[{'subject': 'Otavite', 'subjectScheme': 'name'}, {'subject': 'Cadmium cation', 'subjectScheme': 'name'}, {'subject': 'Carbonate anion', 'subjectScheme': 'name'}, {'subject': 'Cadmium(2+) cation', 'subjectScheme': 'IUPAC name'}, {'subject': '22537-48-0', 'subjectScheme': 'CAS number'}, {'subject': '513-78-0', 'subjectScheme': 'CAS number'}, {'subject': 'Cd2+', 'subjectScheme': 'formula'}, {'subject': '(CO3)2-', 'subjectScheme': 'formula'}, {'subject': 'CdCO3', 'subjectScheme': 'formula'}, {'subject': 'Otavite', 'subjectScheme': 'IMA name'}, {'subject': 'non-silicate mineral', 'subjectScheme': 'mineral class'}, {'subject': 'carbonate', 'subjectScheme': 'compound type'}, {'subject': 'carbonates, nitrates, borates', 'subjectScheme': 'Dana class'}, {'subject': 'anhydrous carbonates', 'subjectScheme': 'Dana class'}, {'subject': 'Calcite group (Trigonal: R-3c)', 'subjectScheme': 'Dana group'}, {'subject': '14.01.01.07', 'subjectScheme': 'Dana code'}, {'subject': '05.AB.05', 'subjectScheme': 'Strunz code'}, {'subject': 'Raman scattering', 'subjectScheme': 'variables'}, {'subject': 'FIR', 'subjectScheme': 'variables'}, {'subject': 'MIR', 'subjectScheme': 'variables'}, {'subject': 'band frequency', 'subjectScheme': 'variables'}, {'subject': 'band width', 'subjectScheme': 'variables'}, {'subject': 'band intensity', 'subjectScheme': 'variables'}, {'subject': 'transition and vibration modes', 'subjectScheme': 'variables'}]",,['ASCII']
+10.26302/sshade/experiment_cl_20181202_01,Ion irradiation ($He^+$) of a FRO95002 meteorite pellet probed by NIR spectroscopy,SSHADE/DAYSY (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","NIR spectra of FRO95002 meteorite pellet, before and after ion irradiation at different doses.",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2022-05-27T17:01:41.000Z,2022-05-27T17:01:42.000Z,inist.sshade,mgeg,"extraterrestrial,carbonaceous chondrite,CO,complex organic-mineral mix,matrix FRO95002,complex mineral mix,chondrules FRO95002,CAIs FRO95002,laboratory measurement,bidirectional reflection,macroscopic,NIR,Near-Infrared,reflectance factor","[{'subject': 'extraterrestrial'}, {'subject': 'carbonaceous chondrite'}, {'subject': 'CO'}, {'subject': 'complex organic-mineral mix'}, {'subject': 'matrix FRO95002'}, {'subject': 'complex mineral mix'}, {'subject': 'chondrules FRO95002'}, {'subject': 'CAIs FRO95002'}, {'subject': 'laboratory measurement'}, {'subject': 'bidirectional reflection'}, {'subject': 'macroscopic'}, {'subject': 'NIR'}, {'subject': 'Near-Infrared'}, {'subject': 'reflectance factor'}]",['5 spectra'],['ASCII']
+10.26302/sshade/experiment_zy_20180212_000,VIS-NIR reflectance spectra of CO2 ice particles produced by crushing and sieving a compact slab of CO2 ice,SSHADE/BYPASS (OSUG Data Center),2023.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",The VIS-NIR reflectance spectrum of a piece of compact CO2 ice slab (commercial sample) was measured as well as the spectra of different particle size fractions of crushed CO2 ice produced by crushing the compact ice and dry sieving the powder. Vis multispectral + NIR low resolution and Vis-NIR high resolution spectra.,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-04-28T13:48:34.000Z,2023-04-28T13:48:35.000Z,inist.sshade,mgeg,"laboratory measurement,biconical reflection,imaging,Vis,Visible,NIR,Near-Infrared,reflectance factor,solid CO2,solid,commercial,laboratory,inorganic molecular solid","[{'subject': 'laboratory measurement', 'subjectScheme': 'main'}, {'subject': 'biconical reflection', 'subjectScheme': 'main'}, {'subject': 'imaging', 'subjectScheme': 'main'}, {'subject': 'Vis', 'subjectScheme': 'var'}, {'subject': 'Visible', 'subjectScheme': 'var'}, {'subject': 'NIR', 'subjectScheme': 'var'}, {'subject': 'Near-Infrared', 'subjectScheme': 'var'}, {'subject': 'reflectance factor', 'subjectScheme': 'var'}, {'subject': 'solid CO2', 'subjectScheme': 'name'}, {'subject': 'solid', 'subjectScheme': 'family'}, {'subject': 'commercial', 'subjectScheme': 'origin'}, {'subject': 'laboratory', 'subjectScheme': 'origin'}, {'subject': 'inorganic molecular solid', 'subjectScheme': 'compound type'}]",['8 spectra'],['ASCII']
+10.6084/m9.figshare.22617740,"Additional file 1 of Individual and environmental determinants associated with longer times to access pediatric rheumatology centers for patients with juvenile idiopathic arthritis, a JIR cohort study",figshare,2023.0,,Text,Creative Commons Attribution 4.0 International,Additional file 1. Location of the 20 pediatric rheumatology centers (using Google Maps).,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-04-13T16:35:35.000Z,2023-04-13T16:35:36.000Z,figshare.ars,otjm,"Medicine,Biotechnology,Ecology,FOS: Biological sciences,Immunology,FOS: Clinical medicine,Cancer,Science Policy","[{'subject': 'Medicine'}, {'subject': 'Biotechnology'}, {'subject': 'Ecology'}, {'subject': 'FOS: Biological sciences', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': 'Immunology'}, {'subject': 'FOS: Clinical medicine', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': 'Cancer'}, {'subject': 'Science Policy'}]",['99200 Bytes'],
+10.15778/resif.yp2012,Seismic network YP: CIFALPS temporary experiment (China-Italy-France Alps seismic transect),RESIF - Réseau Sismologique et géodésique Français,2016.0,en,Dataset,"Open Access,Creative Commons Attribution 4.0 International","Temporary seismic array of broadband stations deployed along a transect across the southwestern Alps (France and Italy). Duration: 14 months. 46 stations in the linear array from the Rhone valley to the central Po plain; 5 to 10 km spacing. 9 offline station at ~40 km distance north and south of the linear array. Goal: imaging of the crust and upper mantle using earthquakes and noise records. Sensors: mostly Nanometrics Trillium-120, with a few Güralp CMG3ESP (90s) and Güralp CMG40T (60s). Digitizers: Nanometrics Taurus.",mds,True,findable,0.0,0.0,0.0,2.0,0.0,2016-10-24T15:38:57.000Z,2016-10-24T15:38:57.000Z,inist.resif,vcob,"Western Alps,Structure of the crust and upper mantle,Seismic tomography,Geodynamics","[{'subject': 'Western Alps'}, {'subject': 'Structure of the crust and upper mantle'}, {'subject': 'Seismic tomography'}, {'subject': 'Geodynamics'}]",['806 Gb; 56 stations'],"['miniseed data', 'stationXML metadata']"
+10.6084/m9.figshare.c.6910186,Cefoxitin versus carbapenems as definitive treatment for extended-spectrum β-lactamase-producing Klebsiella pneumoniae bacteremia in intensive care unit: a propensity-matched retrospective analysis,figshare,2023.0,,Collection,Creative Commons Attribution 4.0 International,"Abstract Background Despite cefoxitin's in vitro resistance to hydrolysis by extended-spectrum beta-lactamases (ESBL), treatment of ESBL-producing Klebsiella pneumoniae (KP) infections with cefoxitin remains controversial. The aim of our study was to compare the clinical efficacy of cefoxitin as definitive antibiotic therapy for patients with ESBL-KP bacteremia in intensive care unit, versus carbapenem therapy. Methods This retrospective study included all patients with monomicrobial bacteremia hospitalized in intensive care unit between January 2013 and January 2023 at the University Hospital of Guadeloupe. The primary outcome was the 30-day clinical success defined as a composite endpoint: 30-day survival, absence of relapse and no change of antibiotic therapy. Cox regression including a propensity score (PS) and PS-based matched analysis were performed for endpoint analysis. Results A total of 110 patients with bloodstream infections were enrolled. Sixty-three patients (57%) received definitive antibiotic therapy with cefoxitin, while forty-seven (43%) were treated with carbapenems. 30-day clinical success was not significantly different between patients treated with cefoxitin (57%) and carbapenems (53%, p = 0.823). PS-adjusted and PS-matched analysis confirmed these findings. Change of definitive antibiotic therapy was more frequent in the cefoxitin group (17% vs. 0%, p = 0.002). No significant differences were observed for the other secondary endpoints. The acquisition of carbapenem-resistant Pseudomonas aeruginosa was significantly higher in patients receiving carbapenem therapy (5% vs. 23%, p = 0.007). Conclusions Our results suggest that cefoxitin as definitive antibiotic therapy could be a therapeutic option for some ESBL-KP bacteremia, sparing carbapenems and reducing the selection of carbapenem-resistant Pseudomonas aeruginosa strains.",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-11-02T05:00:07.000Z,2023-11-02T05:00:08.000Z,figshare.ars,otjm,"Space Science,Medicine,Microbiology,FOS: Biological sciences,Cancer,Infectious Diseases,FOS: Health sciences","[{'subject': 'Space Science'}, {'subject': 'Medicine'}, {'subject': 'Microbiology'}, {'subject': 'FOS: Biological sciences', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': 'Cancer'}, {'subject': 'Infectious Diseases'}, {'subject': 'FOS: Health sciences', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}]",,
+10.26302/sshade/bandlist_raman_vaterite,Raman bandlist of Vaterite,SSHADE/BANDLIST (OSUG Data Center),2023.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",MIR-FIR Raman bandlist of natural and synthetic Vaterite at 295K,mds,True,findable,0.0,0.0,3.0,0.0,0.0,2023-12-24T21:10:49.000Z,2023-12-24T21:10:50.000Z,inist.sshade,mgeg,"Vaterite,Calcium cation,Carbonate anion,Calcium(2+) cation,14127-61-8,Ca2+,(CO3)2-,CaCO3,Vaterite,non-silicate mineral,carbonate,carbonates, nitrates, borates,anhydrous carbonates,Vaterite group,14.01.02.01,05.AB.20,Raman scattering,MIR,FIR,band frequency,band width,band intensity,transition and vibration modes","[{'subject': 'Vaterite', 'subjectScheme': 'name'}, {'subject': 'Calcium cation', 'subjectScheme': 'name'}, {'subject': 'Carbonate anion', 'subjectScheme': 'name'}, {'subject': 'Calcium(2+) cation', 'subjectScheme': 'IUPAC name'}, {'subject': '14127-61-8', 'subjectScheme': 'CAS number'}, {'subject': 'Ca2+', 'subjectScheme': 'formula'}, {'subject': '(CO3)2-', 'subjectScheme': 'formula'}, {'subject': 'CaCO3', 'subjectScheme': 'formula'}, {'subject': 'Vaterite', 'subjectScheme': 'IMA name'}, {'subject': 'non-silicate mineral', 'subjectScheme': 'mineral class'}, {'subject': 'carbonate', 'subjectScheme': 'compound type'}, {'subject': 'carbonates, nitrates, borates', 'subjectScheme': 'Dana class'}, {'subject': 'anhydrous carbonates', 'subjectScheme': 'Dana class'}, {'subject': 'Vaterite group', 'subjectScheme': 'Dana group'}, {'subject': '14.01.02.01', 'subjectScheme': 'Dana code'}, {'subject': '05.AB.20', 'subjectScheme': 'Strunz code'}, {'subject': 'Raman scattering', 'subjectScheme': 'variables'}, {'subject': 'MIR', 'subjectScheme': 'variables'}, {'subject': 'FIR', 'subjectScheme': 'variables'}, {'subject': 'band frequency', 'subjectScheme': 'variables'}, {'subject': 'band width', 'subjectScheme': 'variables'}, {'subject': 'band intensity', 'subjectScheme': 'variables'}, {'subject': 'transition and vibration modes', 'subjectScheme': 'variables'}]",,['ASCII']
+10.26302/sshade/experiment_kd_20220525,"Optical constants of Mg- and Fe-rich amorphous silicate Mg$_{(1-x)}$Fe$_x$SiO$_3$, x=0.1 - 0.2 - 0.3 - 0.4, 10-300 K, UV-mm range",SSHADE/STOPCODA (OSUG Data Center),2022.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","UV to mm optical constants of four Mg- and Fe-rich amorphous silicates Mg$_{(1-x)}$Fe$_x$SiO$_3$, x=0.1 - 0.2 - 0.3 - 0.4, at 10, 100, 200 and 300 K. The optical constants are calculated from mass absorption coefficients measured in the 5 - 1000 µm (2000-10 cm-1) range and extrapolated in the range 0.024 - 5 µm and 1000 - 100000 µm.",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2022-05-31T13:17:49.000Z,2022-05-31T13:17:51.000Z,inist.sshade,mgeg,"solid,laboratory,non-oxide ceramic,Amorphous silicate Mg$_{(1-x)}$Fe$_x$SiO$_3$, x=0.1,commercial,homopolymer,Polyethylene HDPE,bromide,Potassium bromide KBr,Amorphous silicate Mg$_{(1-x)}$Fe$_x$SiO$_3$, x=0.2,Amorphous silicate Mg$_{(1-x)}$Fe$_x$SiO$_3$, x=0.3,Amorphous silicate Mg$_{(1-x)}$Fe$_x$SiO$_3$, x=0.4,laboratory measurement,numerical extrapolation,macroscopic,UV,Ultraviolet,Vis,Visible,NIR,Near-Infrared,MIR,Mid-Infrared,FIR,Far-Infrared,sub-mm,mm,millimeter wave,cm,centimeter wave,optical constants","[{'subject': 'solid'}, {'subject': 'laboratory'}, {'subject': 'non-oxide ceramic'}, {'subject': 'Amorphous silicate Mg$_{(1-x)}$Fe$_x$SiO$_3$, x=0.1'}, {'subject': 'commercial'}, {'subject': 'homopolymer'}, {'subject': 'Polyethylene HDPE'}, {'subject': 'bromide'}, {'subject': 'Potassium bromide KBr'}, {'subject': 'Amorphous silicate Mg$_{(1-x)}$Fe$_x$SiO$_3$, x=0.2'}, {'subject': 'Amorphous silicate Mg$_{(1-x)}$Fe$_x$SiO$_3$, x=0.3'}, {'subject': 'Amorphous silicate Mg$_{(1-x)}$Fe$_x$SiO$_3$, x=0.4'}, {'subject': 'laboratory measurement'}, {'subject': 'numerical extrapolation'}, {'subject': 'macroscopic'}, {'subject': 'UV'}, {'subject': 'Ultraviolet'}, {'subject': 'Vis'}, {'subject': 'Visible'}, {'subject': 'NIR'}, {'subject': 'Near-Infrared'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'FIR'}, {'subject': 'Far-Infrared'}, {'subject': 'sub-mm'}, {'subject': 'mm'}, {'subject': 'millimeter wave'}, {'subject': 'cm'}, {'subject': 'centimeter wave'}, {'subject': 'optical constants'}]",['16 spectra'],['ASCII']
+10.26302/sshade/experiment_gs_20170713_006,Ag K edge XAS transmission of synthetic acanthite Ag2S (nanos),SSHADE/FAME (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2019-12-05T13:14:57.000Z,2019-12-05T13:15:02.000Z,inist.sshade,mgeg,"solid,commercial,non-oxide ceramic,BN powder,laboratory,Synthetic acanthite,laboratory measurement,transmission,None,hard X,hard X-rays","[{'subject': 'solid'}, {'subject': 'commercial'}, {'subject': 'non-oxide ceramic'}, {'subject': 'BN powder'}, {'subject': 'laboratory'}, {'subject': 'Synthetic acanthite'}, {'subject': 'laboratory measurement'}, {'subject': 'transmission'}, {'subject': 'None'}, {'subject': 'hard X'}, {'subject': 'hard X-rays'}]",['1 spectrum'],['ASCII']
+10.6084/m9.figshare.23575381,Additional file 8 of Decoupling of arsenic and iron release from ferrihydrite suspension under reducing conditions: a biogeochemical model,figshare,2023.0,,Text,Creative Commons Attribution 4.0 International,Authors’ original file for figure 7,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-06-25T03:11:57.000Z,2023-06-25T03:11:57.000Z,figshare.ars,otjm,"59999 Environmental Sciences not elsewhere classified,FOS: Earth and related environmental sciences,39999 Chemical Sciences not elsewhere classified,FOS: Chemical sciences,Ecology,FOS: Biological sciences,69999 Biological Sciences not elsewhere classified,Cancer","[{'subject': '59999 Environmental Sciences not elsewhere classified', 'schemeUri': 'http://www.abs.gov.au/ausstats/abs@.nsf/0/6BB427AB9696C225CA2574180004463E', 'subjectScheme': 'FOR'}, {'subject': 'FOS: Earth and related environmental sciences', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': '39999 Chemical Sciences not elsewhere classified', 'schemeUri': 'http://www.abs.gov.au/ausstats/abs@.nsf/0/6BB427AB9696C225CA2574180004463E', 'subjectScheme': 'FOR'}, {'subject': 'FOS: Chemical sciences', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': 'Ecology'}, {'subject': 'FOS: Biological sciences', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': '69999 Biological Sciences not elsewhere classified', 'schemeUri': 'http://www.abs.gov.au/ausstats/abs@.nsf/0/6BB427AB9696C225CA2574180004463E', 'subjectScheme': 'FOR'}, {'subject': 'Cancer'}]",['24064 Bytes'],
+10.26302/sshade/experiment_dt_20180117_001,Cr K edge XAS transmission of Cr metallic foil reference at ambient conditions,SSHADE/FAME (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2019-11-16T07:50:58.000Z,2019-11-16T07:50:59.000Z,inist.sshade,mgeg,"commercial,elemental solid,metallic Cr,laboratory measurement,transmission,None,hard X,hard X-rays","[{'subject': 'commercial'}, {'subject': 'elemental solid'}, {'subject': 'metallic Cr'}, {'subject': 'laboratory measurement'}, {'subject': 'transmission'}, {'subject': 'None'}, {'subject': 'hard X'}, {'subject': 'hard X-rays'}]",['1 spectrum'],['ASCII']
+10.6084/m9.figshare.c.6592129,"Biallelic variants in NOS3 and GUCY1A3, the two major genes of the nitric oxide pathway, cause moyamoya cerebral angiopathy",figshare,2023.0,,Collection,Creative Commons Attribution 4.0 International,"Abstract Background Moyamoya angiopathy (MMA) is a rare cerebrovascular condition leading to stroke. Mutations in 15 genes have been identified in Mendelian forms of MMA, but they explain only a very small proportion of cases. Our aim was to investigate the genetic basis of MMA in consanguineous patients having unaffected parents in order to identify genes involved in autosomal recessive MMA. Methods Exome sequencing (ES) was performed in 6 consecutive consanguineous probands having MMA of unknown etiology. Functional consequences of variants were assessed using western blot and protein 3D structure analyses. Results Causative homozygous variants of NOS3, the gene encoding the endothelial nitric oxide synthase (eNOS), and GUCY1A3, the gene encoding the alpha1 subunit of the soluble guanylate cyclase (sGC) which is the major nitric oxide (NO) receptor in the vascular wall, were identified in 3 of the 6 probands. One NOS3 variant (c.1502 + 1G &gt; C) involves a splice donor site causing a premature termination codon and leads to a total lack of eNOS in endothelial progenitor cells of the affected proband. The other NOS3 variant (c.1942 T &gt; C) is a missense variant located into the flavodoxine reductase domain; it is predicted to be destabilizing and shown to be associated with a reduction of eNOS expression. The GUCY1A3 missense variant (c.1778G &gt; A), located in the catalytic domain of the sGC, is predicted to disrupt the tridimensional structure of this domain and to lead to a loss of function of the enzyme. Both NOS3 mutated probands suffered from an infant-onset and severe MMA associated with posterior cerebral artery steno-occlusive lesions. The GUCY1A3 mutated proband presented an adult-onset MMA associated with an early-onset arterial hypertension and a stenosis of the superior mesenteric artery. None of the 3 probands had achalasia. Conclusions We show for the first time that biallelic loss of function variants in NOS3 is responsible for MMA and that mutations in NOS3 and GUCY1A3 are causing fifty per cent of MMA in consanguineous patients. These data pinpoint the essential role of the NO pathway in MMA pathophysiology.",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-04-13T14:39:37.000Z,2023-04-13T14:47:59.000Z,figshare.ars,otjm,"Genetics,FOS: Biological sciences","[{'subject': 'Genetics'}, {'subject': 'FOS: Biological sciences', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}]",,
+10.26302/sshade/experiment_op_20230207_001,"VIS-NIR-MIR Reflectance spectra of mixtures of sub-µm grains of Olivine with Iron Sulfides or Anthracite, at different concentrations",SSHADE/GhoSST (OSUG Data Center),2023.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",We measured the reflectance spectra (from 0.55 to 25 µm) of mixtures of sub-µm grains of Olivine with Iron Sulfides or Anthracite.,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-02-07T21:19:38.000Z,2023-02-07T21:19:38.000Z,inist.sshade,mgeg,"mineral,laboratory,natural terrestrial,nesosilicate,Olivine Forsterite,tektosilicate,Quartz,commercial,sulfide,Troilite,Pyrrhotite,complex macromolecular mixture,Anthracite,laboratory measurement,transmission,macroscopic,NIR,Near-Infrared,MIR,Mid-Infrared,bidirectional reflection,Vis,Visible,reflectance factor","[{'subject': 'mineral'}, {'subject': 'laboratory'}, {'subject': 'natural terrestrial'}, {'subject': 'nesosilicate'}, {'subject': 'Olivine Forsterite'}, {'subject': 'tektosilicate'}, {'subject': 'Quartz'}, {'subject': 'commercial'}, {'subject': 'sulfide'}, {'subject': 'Troilite'}, {'subject': 'Pyrrhotite'}, {'subject': 'complex macromolecular mixture'}, {'subject': 'Anthracite'}, {'subject': 'laboratory measurement'}, {'subject': 'transmission'}, {'subject': 'macroscopic'}, {'subject': 'NIR'}, {'subject': 'Near-Infrared'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'bidirectional reflection'}, {'subject': 'Vis'}, {'subject': 'Visible'}, {'subject': 'reflectance factor'}]",['22 spectra'],['ASCII']
+10.26302/sshade/experiment_yd_20220602_010,Multiangular reflectance of Ysson amorphous/crystalline mixture in 5 visible spectral bands for 2 different grain sizes,SSHADE/PaSSTEL (OSUG Data Center),2022.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","Multiangular reflectance (23 angular configurations) of Ysson amorphous/crystalline mixture (synthetic glass/natural basalt) in 5 visible spectral bands (0.56, 0.70, 0.79, 0.88, 0.96 µm) and for 2 different grain size ranges (125-250, 250-500 µm)",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2022-06-03T12:48:53.000Z,2022-06-03T12:48:54.000Z,inist.sshade,mgeg,"solid,laboratory,natural terrestrial,tektosilicate,Glass,mineral,Vitreous matrix,nesosilicate,Olivine,inosilicate,Pyroxene,Plagioclase,laboratory measurement,bidirectional reflection,imaging,Vis,Visible,reflectance factor","[{'subject': 'solid'}, {'subject': 'laboratory'}, {'subject': 'natural terrestrial'}, {'subject': 'tektosilicate'}, {'subject': 'Glass'}, {'subject': 'mineral'}, {'subject': 'Vitreous matrix'}, {'subject': 'nesosilicate'}, {'subject': 'Olivine'}, {'subject': 'inosilicate'}, {'subject': 'Pyroxene'}, {'subject': 'Plagioclase'}, {'subject': 'laboratory measurement'}, {'subject': 'bidirectional reflection'}, {'subject': 'imaging'}, {'subject': 'Vis'}, {'subject': 'Visible'}, {'subject': 'reflectance factor'}]",['6 spectra'],['ASCII']
+10.26302/sshade/experiment_rb_20130101_002,"Ion irradiation ($He^+$, $Ar^+$) of a Murchison meteorite pellets probed by Raman spectroscopy",SSHADE/DAYSY (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","Raman spectra of pellets 1 and 2 of the Murchison meteorite, with different irradiation spots on the surface. Raman micro-spectroscopy was performed at the SMIS beamline at SOLEIL using a DXR Raman micro-spectrometer from Thermo Fisher with a 532 nm exciting laser radiation, and a power on the sample lower than 0.3 mW, producing power densities lower than 300 $W/mm^2$.",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2022-05-27T17:02:53.000Z,2022-05-27T17:02:54.000Z,inist.sshade,mgeg,"extraterrestrial,carbonaceous chondrite,CM,complex organic-mineral mix,matrix Murchison,complex mineral mix,chondrules Murchison,CAIs Murchison,laboratory measurement,Raman scattering,micro-imaging,MIR,Mid-Infrared,Raman scattering intensity","[{'subject': 'extraterrestrial'}, {'subject': 'carbonaceous chondrite'}, {'subject': 'CM'}, {'subject': 'complex organic-mineral mix'}, {'subject': 'matrix Murchison'}, {'subject': 'complex mineral mix'}, {'subject': 'chondrules Murchison'}, {'subject': 'CAIs Murchison'}, {'subject': 'laboratory measurement'}, {'subject': 'Raman scattering'}, {'subject': 'micro-imaging'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'Raman scattering intensity'}]",['6 spectra'],['ASCII']
+10.26302/sshade/experiment_nf_20180503_2100,MIR absorbance spectra of CO ice at 25K for different deposition rates and different thicknesses,SSHADE/SCOOP (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",MIR absorbance spectra of CO ice at 25K for different deposition rates (0.04-1.05 nm/s) and different thicknesses (90-4630 nm),mds,True,findable,0.0,0.0,0.0,0.0,0.0,2022-04-30T11:01:45.000Z,2022-04-30T11:01:45.000Z,inist.sshade,mgeg,"laboratory,inorganic molecular solid,CO ice,laboratory measurement,transmission,macroscopic,MIR,Mid-Infrared,absorbance","[{'subject': 'laboratory'}, {'subject': 'inorganic molecular solid'}, {'subject': 'CO ice'}, {'subject': 'laboratory measurement'}, {'subject': 'transmission'}, {'subject': 'macroscopic'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'absorbance'}]",['17 spectra'],['ASCII']
+10.6084/m9.figshare.c.7009820,Barriers and facilitators to the HPV vaccine: a multicenter qualitative study of French general practitioners,figshare,2024.0,,Collection,Creative Commons Attribution 4.0 International,"Abstract Background In France, human papillomavirus (HPV) vaccination coverage is low, with 30.7% of 17-year-old girls having received a complete HPV vaccination schedule in 2020. Aim To determine the perspective and behaviors of general practitioners (GPs) regarding HPV vaccination with their patients and if a reluctance is observed. Design and setting A qualitative study based on semi-directed individual interviews was conducted between December 2019 and December 2020. A representative sample of GPs with various profiles were included in 4 French regions. Method A purposive sampling was used and interviews were continued until data saturation was reached. The analysis was based on the grounded theory. Results Twenty-six GPs aged 29–66 years were interviewed. The measures taken by the French health authorities (lowering the target age, reimbursing the vaccine, extending the target population to boys) were perceived as facilitators. The reported barriers were organizational, due to low attendance of adolescents, and relational, mainly due to parental vaccine hesitancy. Physicians had to deal with fears about the perceived risks and concerns about sexuality conveyed by HPV vaccination and linked to the socio-cultural characteristics of the families. Physicians developed strategies, including scientific knowledge mobilization, empowerment of families by promoting health through prevention, repetition of the vaccination proposals, personal experience and relationship. Different practices were identified according to three GP typologies: effective, convinced but unpersuasive, and reluctant physicians. Conclusion Based on these results, specific interventions, including communication techniques, especially for hesitant or unpersuasive physicians, are needed to enable GPs to become more effective.",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2024-01-05T04:41:35.000Z,2024-01-05T04:41:36.000Z,figshare.ars,otjm,"Biological Sciences not elsewhere classified,Cancer,Science Policy,Infectious Diseases,FOS: Health sciences","[{'subject': 'Biological Sciences not elsewhere classified'}, {'subject': 'Cancer'}, {'subject': 'Science Policy'}, {'subject': 'Infectious Diseases'}, {'subject': 'FOS: Health sciences', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}]",,
+10.5281/zenodo.10517970,CaliParticles: A Benchmark Standard for Experiments in Granular Materials,Zenodo,2024.0,en,Dataset,Creative Commons Attribution 4.0 International,"Granular materials are discrete particulate media that can flow like a liquid but also be rigid like a solid. This complex mechanical behavior originates in part from the particles shape. How particle shape affects mechanical behavior remains poorly understood. Understanding this micro-macro link would enable the rational design of potentially cheap, light weight or robust materials. To aid this development, we have produced a set of standard particle shapes that can be used as benchmarks for granular materials research. Here we describe the collection of benchmark shapes. Some part of the particles are modeled on superquadrics, others are custom designed. The particles used so far were made from polyoxymethylene (POM) and Thermoplastic elastomers (TPE) whose specifications are also listed. The benchmark shapes are available as molds in a plastics manufacturing company, whose contact information is also included. The company is capable of making other molds as well, giving access to more particle shapes. The same particle shapes can thus also be made in different types of (colored) plastic, and in amounts of 50.000 particles or more, larger than conveniently be produced with a 3D printer. We also provide the associated .step and .stl files in the repository in which this document is included. ",api,True,findable,0.0,0.0,0.0,0.0,0.0,2024-01-16T10:37:36.000Z,2024-01-16T10:37:36.000Z,cern.zenodo,cern,"Particles,Macaroni,Ellipsoid,Tetrapod,Hexapod,Sphereotetrahedron,Caliper","[{'subject': 'Particles'}, {'subject': 'Macaroni'}, {'subject': 'Ellipsoid'}, {'subject': 'Tetrapod'}, {'subject': 'Hexapod'}, {'subject': 'Sphereotetrahedron'}, {'subject': 'Caliper'}]",,
+10.15778/resif.yi2015,"Saint-Guérin Arch Dam Experiment, 2015-2016, code YI, funded by chaire Pereniti (Grenoble INP, EDF), Université Grenoble Alpes, instrumented by RESIF-SISMOB",RESIF - Réseau Sismologique et géodésique Français,2017.0,en,Dataset,"Open Access,Creative Commons Attribution 4.0 International","The Saint-Guérin arch dam experiment consists of a dense network of 19 broadband velocimeters deployed for one year on and around the Saint-Guérin arch dam (french Alps) in order (i) to capture the spatial variability of seismic ground motions at the dam-foundation interface, (ii) to measure the seismic response at the dam crest and (iii) to monitor the variations of the seismic response of the dam and its surroundings caused by environemental changes (water elevation, temperature).",mds,True,findable,0.0,0.0,0.0,1.0,0.0,2017-11-22T11:24:15.000Z,2017-11-22T11:24:15.000Z,inist.resif,vcob,"Dense seismic array,Spatial variability,Seismic ground motion,Arch dam,Engineering seismology,Earthquake engineering,Structural dynamics","[{'subject': 'Dense seismic array'}, {'subject': 'Spatial variability'}, {'subject': 'Seismic ground motion'}, {'subject': 'Arch dam'}, {'subject': 'Engineering seismology'}, {'subject': 'Earthquake engineering'}, {'subject': 'Structural dynamics'}]",['Approx. 307 Gb;19 stations'],"['Miniseed data data', 'stationXML metadata']"
+10.26302/sshade/experiment_la_20201113_000,VIS-NIR reflectance spectra of 6 different particles size fractions of the Mars Global Simulant MGS-1 (CLASS Exolith Lab - UCF),SSHADE/BYPASS (OSUG Data Center),2023.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",Six different particle size fractions of the Mars regolith simulant MGS-1 were separated by dry sieving with a Varisfiter sonic separator. Their respective VIS-NIR reflectance spectra were then measured with the MoHIS hyperspectral imager.,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-06-16T12:37:06.000Z,2023-06-16T12:37:07.000Z,inist.sshade,mgeg,"laboratory measurement,biconical reflection,imaging,Vis,Visible,NIR,Near-Infrared,reflectance factor,Anorthite,Olivine,Pyroxene,Plagioclase,Volcanic glass,Mg-sulfate,Ferrihydrite,Hydrated silica,Magnetite,Anhydrite,Fe-carbonate,Hematite,mineral,laboratory,natural terrestrial,tektosilicate,nesosilicate,inosilicate,sulfate,oxide-hydroxide,silicate,carbonate","[{'subject': 'laboratory measurement', 'subjectScheme': 'main'}, {'subject': 'biconical reflection', 'subjectScheme': 'main'}, {'subject': 'imaging', 'subjectScheme': 'main'}, {'subject': 'Vis', 'subjectScheme': 'variables'}, {'subject': 'Visible', 'subjectScheme': 'variables'}, {'subject': 'NIR', 'subjectScheme': 'variables'}, {'subject': 'Near-Infrared', 'subjectScheme': 'variables'}, {'subject': 'reflectance factor', 'subjectScheme': 'variables'}, {'subject': 'Anorthite', 'subjectScheme': 'name'}, {'subject': 'Olivine', 'subjectScheme': 'name'}, {'subject': 'Pyroxene', 'subjectScheme': 'name'}, {'subject': 'Plagioclase', 'subjectScheme': 'name'}, {'subject': 'Volcanic glass', 'subjectScheme': 'name'}, {'subject': 'Mg-sulfate', 'subjectScheme': 'name'}, {'subject': 'Ferrihydrite', 'subjectScheme': 'name'}, {'subject': 'Hydrated silica', 'subjectScheme': 'name'}, {'subject': 'Magnetite', 'subjectScheme': 'name'}, {'subject': 'Anhydrite', 'subjectScheme': 'name'}, {'subject': 'Fe-carbonate', 'subjectScheme': 'name'}, {'subject': 'Hematite', 'subjectScheme': 'name'}, {'subject': 'mineral', 'subjectScheme': 'family'}, {'subject': 'laboratory', 'subjectScheme': 'origin'}, {'subject': 'natural terrestrial', 'subjectScheme': 'origin'}, {'subject': 'tektosilicate', 'subjectScheme': 'compound type'}, {'subject': 'nesosilicate', 'subjectScheme': 'compound type'}, {'subject': 'inosilicate', 'subjectScheme': 'compound type'}, {'subject': 'sulfate', 'subjectScheme': 'compound type'}, {'subject': 'oxide-hydroxide', 'subjectScheme': 'compound type'}, {'subject': 'silicate', 'subjectScheme': 'compound type'}, {'subject': 'carbonate', 'subjectScheme': 'compound type'}]",['6 spectra'],['ASCII']
+10.26302/sshade/experiment_lb_20191211_005,Fe K edge XAS transmission of bulk CV carbonaceous chondrites,SSHADE/GhoSST+FAME (OSUG Data Center),2020.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",raw and normalized Fe K edge XAS transmission of bulk CV carbonaceous chondrites,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2019-12-13T13:06:18.000Z,2019-12-13T13:06:19.000Z,inist.sshade,mgeg,"solid,commercial,non-oxide ceramic,BN powder,extraterrestrial,carbonaceous chondrite,CV,complex organic-mineral mix,matrix Allende IPAG,complex mineral mix,chondrules Allende IPAG,CAIs Allende IPAG,matrix Bali IPAG,chondrules Bali IPAG,CAIs Bali IPAG,matrix Grosnaja IPAG,chondrules Grosnaja IPAG,CAIs Grosnaja IPAG,matrix Efremovka IPAG,chondrules Efremovka IPAG,CAIs Efremovka IPAG,matrix Kaba IPAG,chondrules Kaba IPAG,CAIs Kaba IPAG,matrix Mokoia IPAG,chondrules Mokoia IPAG,CAIs Mokoia IPAG,matrix Leoville IPAG,chondrules Leoville IPAG,CAIs Leoville IPAG,matrix Vigarano IPAG,chondrules Vigarano IPAG,CAIs Vigarano IPAG,matrix RBT04133 IPAG,chondrules RBT04133 IPAG,CAIs RBT04133 IPAG,matrix Axtell IPAG,chondrules Axtell IPAG,CAIs Axtell IPAG,laboratory measurement,transmission,None,hard X,raw,normalized absorbance","[{'subject': 'solid'}, {'subject': 'commercial'}, {'subject': 'non-oxide ceramic'}, {'subject': 'BN powder'}, {'subject': 'extraterrestrial'}, {'subject': 'carbonaceous chondrite'}, {'subject': 'CV'}, {'subject': 'complex organic-mineral mix'}, {'subject': 'matrix Allende IPAG'}, {'subject': 'complex mineral mix'}, {'subject': 'chondrules Allende IPAG'}, {'subject': 'CAIs Allende IPAG'}, {'subject': 'matrix Bali IPAG'}, {'subject': 'chondrules Bali IPAG'}, {'subject': 'CAIs Bali IPAG'}, {'subject': 'matrix Grosnaja IPAG'}, {'subject': 'chondrules Grosnaja IPAG'}, {'subject': 'CAIs Grosnaja IPAG'}, {'subject': 'matrix Efremovka IPAG'}, {'subject': 'chondrules Efremovka IPAG'}, {'subject': 'CAIs Efremovka IPAG'}, {'subject': 'matrix Kaba IPAG'}, {'subject': 'chondrules Kaba IPAG'}, {'subject': 'CAIs Kaba IPAG'}, {'subject': 'matrix Mokoia IPAG'}, {'subject': 'chondrules Mokoia IPAG'}, {'subject': 'CAIs Mokoia IPAG'}, {'subject': 'matrix Leoville IPAG'}, {'subject': 'chondrules Leoville IPAG'}, {'subject': 'CAIs Leoville IPAG'}, {'subject': 'matrix Vigarano IPAG'}, {'subject': 'chondrules Vigarano IPAG'}, {'subject': 'CAIs Vigarano IPAG'}, {'subject': 'matrix RBT04133 IPAG'}, {'subject': 'chondrules RBT04133 IPAG'}, {'subject': 'CAIs RBT04133 IPAG'}, {'subject': 'matrix Axtell IPAG'}, {'subject': 'chondrules Axtell IPAG'}, {'subject': 'CAIs Axtell IPAG'}, {'subject': 'laboratory measurement'}, {'subject': 'transmission'}, {'subject': 'None'}, {'subject': 'hard X'}, {'subject': 'raw'}, {'subject': 'normalized absorbance'}]",['20 spectra'],['ASCII']
+10.26302/sshade/experiment_lb_20200914_001,"Vis-NIR reflectance spectra (i = 0°, e = 30°) of three lithologies (raw + powder) of the CM2 chondrite Aguas Zarcas under ambient conditions",SSHADE/GhoSST (OSUG Data Center),2020.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","Vis-NIR reflectance spectra (i = 0°, e = 30°) of 3 different lithologies (raw and powdered samples) of the CM2 chondrite Aguas Zarcas under ambient conditions",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2020-09-28T09:14:32.000Z,2020-09-28T09:14:33.000Z,inist.sshade,mgeg,"extraterrestrial,carbonaceous chondrite,CM,complex organic-mineral mix,matrix,complex mineral mix,chondrules,CAIs,laboratory measurement,bidirectional reflection,macroscopic,Vis,Visible,NIR,Near-Infrared,reflectance factor","[{'subject': 'extraterrestrial'}, {'subject': 'carbonaceous chondrite'}, {'subject': 'CM'}, {'subject': 'complex organic-mineral mix'}, {'subject': 'matrix'}, {'subject': 'complex mineral mix'}, {'subject': 'chondrules'}, {'subject': 'CAIs'}, {'subject': 'laboratory measurement'}, {'subject': 'bidirectional reflection'}, {'subject': 'macroscopic'}, {'subject': 'Vis'}, {'subject': 'Visible'}, {'subject': 'NIR'}, {'subject': 'Near-Infrared'}, {'subject': 'reflectance factor'}]",['6 spectra'],['ASCII']
+10.26302/sshade/experiment_op_20180111_001,Vis-NIR reflectance spectra of biomolecules dry powders at 293±2 K,SSHADE/BYPASS (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","Reflectance spectra (from 0.38 to 2.4 µm) of commercial powders of some of the main terrestrial biomolecules were measured at room temperature (~293 K) and pressure (~1 atm): proteins, DNA, phospholipids, carbohydrates, pigments (porphyrins, carotenoid)",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2020-03-31T11:12:35.000Z,2020-03-31T11:12:37.000Z,inist.sshade,mgeg,"carbonaceous,commercial,organic molecular solid,Bovine serum albumin (BSA),Hemoglobin human,1,2-dipalmitoyl-rac-glycero-3-phosphatidic acid disodium salt,1,2-Dihexadecyl-rac-glycero-3-phosphocholine,Deoxyribonucleic acid sodium salt (DNA),Cellulose,Chlorophyllin sodium copper salt,Hemin,all-trans-Retinal,laboratory measurement,biconical reflection,imaging,Vis,Visible,NIR,Near-Infrared,reflectance factor","[{'subject': 'carbonaceous'}, {'subject': 'commercial'}, {'subject': 'organic molecular solid'}, {'subject': 'Bovine serum albumin (BSA)'}, {'subject': 'Hemoglobin human'}, {'subject': '1,2-dipalmitoyl-rac-glycero-3-phosphatidic acid disodium salt'}, {'subject': '1,2-Dihexadecyl-rac-glycero-3-phosphocholine'}, {'subject': 'Deoxyribonucleic acid sodium salt (DNA)'}, {'subject': 'Cellulose'}, {'subject': 'Chlorophyllin sodium copper salt'}, {'subject': 'Hemin'}, {'subject': 'all-trans-Retinal'}, {'subject': 'laboratory measurement'}, {'subject': 'biconical reflection'}, {'subject': 'imaging'}, {'subject': 'Vis'}, {'subject': 'Visible'}, {'subject': 'NIR'}, {'subject': 'Near-Infrared'}, {'subject': 'reflectance factor'}]",['9 spectra'],['ASCII']
+10.26302/sshade/experiment_bs_20120803_001,Near-IR bidirectional reflection spectra (i=0°/e=30°) of Smectite SWy-2 with different amounts of adsorbed H2O at -30°C,SSHADE/GhoSST (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","Near-IR bidirectional reflection spectra (at fixed geometry: i=0°/e=30°) of Smectite SWy-2 with different amounts of adsorbed H2O at -30°C, under increasing, then decreasing pressure of H2O vapor.",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2019-11-02T08:57:38.000Z,2019-11-02T08:57:39.000Z,inist.sshade,mgeg,"natural terrestrial,phyllosilicate,Na-Montmorillonite,physically adsorbed phase,Adsorbed water,tektosilicate,Quartz,Plagioclase,sulfate,Gypsum,carbonate,Calcite,Dolomite,Kaolinite,Chlorites,inosilicate,Clinopyroxenes,Orthopyroxenes,laboratory measurement,bidirectional reflection,macroscopic,NIR,Near-Infrared,reflectance factor","[{'subject': 'natural terrestrial'}, {'subject': 'phyllosilicate'}, {'subject': 'Na-Montmorillonite'}, {'subject': 'physically adsorbed phase'}, {'subject': 'Adsorbed water'}, {'subject': 'tektosilicate'}, {'subject': 'Quartz'}, {'subject': 'Plagioclase'}, {'subject': 'sulfate'}, {'subject': 'Gypsum'}, {'subject': 'carbonate'}, {'subject': 'Calcite'}, {'subject': 'Dolomite'}, {'subject': 'Kaolinite'}, {'subject': 'Chlorites'}, {'subject': 'inosilicate'}, {'subject': 'Clinopyroxenes'}, {'subject': 'Orthopyroxenes'}, {'subject': 'laboratory measurement'}, {'subject': 'bidirectional reflection'}, {'subject': 'macroscopic'}, {'subject': 'NIR'}, {'subject': 'Near-Infrared'}, {'subject': 'reflectance factor'}]",['21 spectra'],['ASCII']
+10.5281/zenodo.10592270,silx-kit/silx: 2.0.0: 2024/01/30,Zenodo,2024.0,,Software,Creative Commons Attribution 4.0 International,"This version of silx supports Python 3.7 to 3.12.
+This is the last version of silx supporting Python 3.7.
+The silx.gui package supports PySide6, PyQt6 and PyQt5 (PySide2 is no longer supported).
+
+Breaking API change: silx.gui.plot.PlotWidget's add methods (i.e., addCurve, addImage, ...) returns the plot item object instance instead of its legend (https://github.com/silx-kit/silx/pull/3996).
+
+<details><summary>
+
+What's Changed...
+
+</summary>
+
+silx applications
+
+
+
+
+Added silx compare, a dedicated application to compare images (PR #3788, #3827, #3884, #3943, #3944)
+
+
+
+silx view:
+
+
+
+Added --slices option (PR #3860)
+
+Added supports for data URL containing ""**"" to match multiple sub groups (PR #3795)
+
+Added keyboard shortcuts for open/close all (PR #3863)
+
+Improved: Stopped displaying a message box for each error (PR #3955)
+
+Improved: Use matplotlib if OpenGL is not available (PR #3905)
+
+Fixed support of NXData image with 0-length axis (PR #3768)
+
+Fixed setting focus at startup when opening a dataset (PR #3953)
+
+
+
+
+silx.app.utils: Refactored (PR #3811)
+
+
+
+silx.io
+
+
+
+
+silx.io.dictdump:
+
+
+
+Removed dicttoh5's overwrite_data argument (PR #3806)
+
+Improved error message for dicttoh5 with non-serializable data (PR #3937)
+
+Fixed h5todict errors argument issue (PR #3749) and fixed-length string issue (PR #3748)
+
+
+
+
+silx.io.h5py_utils:
+
+
+
+Fixed retry (PR #3775)
+
+Fixed: Do not call multiprocessing module in frozen binaries (PR #3984)
+
+
+
+
+silx.io.nxdata.parser: Fixed NXdata validation (PR #3782)
+
+
+
+silx.io.url:
+
+
+
+Added support of URLs with slices to DataUrl (PR #3821)
+
+Added typings for DataUrl (PR #3968)
+
+Fixed DataUrl: Allow file_path to be None (PR #4051)
+
+
+
+
+silx.io.utils:
+
+
+
+Added support of bare file to get_data with check_schemas=True argument (PR #3859)
+
+Improved: open do not lock the file (PR #3939)
+
+Fixed small/big endian support in test (PR #3873)
+
+Fixed h5py_read_dataset support of empty arrays (PR #4052)
+
+
+
+
+silx.math
+
+
+
+Fixed several function docstrings (PR #3774)
+
+silx.math.colormap: Added normalize function to normalize to uint8 (PR #3785)
+
+silx.math.fit: Added split pseudo-voigt with split lorentzian fraction (PR #3902)
+
+
+silx.opencl
+
+
+
+
+Fixed regression with PoCL and order of floating point operations (PR #3935)
+
+
+
+Fixed: skip test on broken platform (PR #3809)
+
+
+
+Fixed: prevent crash at init when loading silx with PortableCL + Cuda devices (PR #3924)
+
+
+
+silx.opencl.atomic: Added new checking for atomic32 and atomic64 operation (PR #3855)
+
+
+
+silx.opencl.backprojection: Removed deprecated fourier_filter function (PR #3816)
+
+
+
+silx.opencl.codec:
+
+
+
+Added `bitshuffle_lz4`` decompression (PR #3714)
+
+Added support of pyopencl's Buffer and Array to BitshuffleLz4.decompress (PR #3787)
+
+
+
+
+`silx.opencl.common``:
+
+
+
+Removed OpenCL.create_context useFp64 argument (PR #3801)
+
+Reworked initialisation of the module (PR #3903)
+
+Updated: Defer to pyopencl the interpretation of PYOPENCL_CTX (PR #3933)
+
+
+
+
+silx.opencl.convolution: Removed Python 2 compatible code (PR #3818)
+
+
+
+silx.third_party
+
+
+
+Removed copy of scipy's Delaunay from third_party (PR #3808)
+
+Deprecated EdfFile and TiffIO (PR #3841)
+
+
+silx.gui
+
+
+
+
+silx.gui:
+
+
+
+Added support for QT_API environment variable (PR #3981)
+
+Added a warning about pyOpenGL and Qt compatibility (PR #3738)
+
+Added some Python typing (PR #3957)
+
+Removed support of  PySide6<6.4 (PR #3872)
+
+Improved qWidgetFactory test fixture (PR #4009)
+
+Fixed support of PySide 6.4 enums (PR #3737)
+
+Fixed support of PyQt6 (PR #3960, #3966, #3989, #3999, #4003)
+
+Fixed support of OpenGL with python3.12 and pyopengl <=3.1.7 (PR #3982)
+
+Fixed OpenGL version parsing (PR #3733)
+
+
+
+
+silx.gui.colors:
+
+
+
+Added indexed color names support to rgba (PR #3836, #3861)
+
+Added typing (PR #3974)
+
+silx.gui.colors.rgba: Changed from AssertionError to ValueError (PR #3864)
+
+Improved: Colormap.setVRange raises an exception if the range is not finite (PR #3794)
+
+
+
+
+silx.gui.constants: Added: expose URI used to drag and drop DataUrl (PR #3796)
+
+
+
+silx.gui.data:
+
+
+
+Fixed issue with hdf5 attributes string formatting (PR #3790)
+
+silx.gui.data.DataView: Removed patch for pymca <v5.3.0 support (PR #3800)
+
+silx.gui.data.HDF5TableView: Fixed virtual and external dataset information (PR #3717)
+
+silx.gui.data.RecordTableView: Fixed issue with datasets with many rows failing to load due to incorrect variable type (PR #3926)
+
+
+
+
+silx.gui.dialog:
+
+
+
+
+silx.gui.dialog.ColormapDialog:
+
+
+
+Added DisplayMode to API by renaming _DataInPlotMode (PR #3964)
+
+Fixed layout (PR #3792)
+
+Fixed state when updating Item (PR #3833)
+
+Fixed robustness of tools with item inheriting from ImageBase (PR #3858)
+
+
+
+
+
+
+silx.gui.hdf5:
+
+
+
+Added NXnote to the list of describable classes (PR #3832)
+
+Added tests for H5Node soft link to an external link issue (PR #3220)
+
+
+
+
+silx.gui.qt:
+
+
+
+Updated PySide6 loadUi function (PR #3783)
+
+Fixed Python>3.9 support (PR #3779)
+
+
+
+
+silx.gui.plot:
+
+
+
+
+silx.gui.plot.actions: Added typings for PlotAction (PR #3941)
+
+
+
+silx.gui.plot.items:
+
+
+
+
+Added Marker item font configuration (PR #3956)
+
+
+
+Added background color for markers and removed automatic background color (PR #4012)
+
+
+
+Added get|setLineGapColor methods to Curve and Histogram (PR #3973)
+
+
+
+Renamed Shape.get|setLineBgColor to get|setLineGapColor (PR #4001)
+
+
+
+Deprecated Curve and Image sequence-like access (PR #3803)
+
+
+
+Improved handling of data ndim and shape for image items (PR #3976)
+
+
+
+Fixed: Removed ImageDataAggregated all-NaN warning (PR #3786)
+
+
+
+Fixed Shape display with dashes and a background color (PR #3906)
+
+
+
+silx.gui.plot.items.roi:
+
+
+
+Added RegionOfInterest's getText and setText methods (PR #3847)
+
+Added populateContextMenu method to ROIs (PR #3891)
+
+Added ArcROI.getPositionRole method (PR #3894)
+
+Added ROIs base classes to documentation (PR #3839)
+
+Removed deprecated methods RegionOfInterest.get|setLabel (PR #3810)
+
+Improved `ArcROI``: Hide the handler instead of hidding the symbol (PR #3887)
+
+Improved: highlighted RegionOfInterest takes priority for interactions (PR #3975)
+
+Fixed ROI initialisation with parent (PR #4053)
+
+
+
+
+
+
+silx.gui.plot.ColorBar: Fixed division by zero issue (PR #4013)
+
+
+
+silx.gui.plot.CompareImages:
+
+
+
+Added profile to compare image (PR #3845)
+
+Improved consistency of autoscale (PR #3823)
+
+Fixed the A-B visualization mode (PR #3856)
+
+
+
+
+silx.gui.plot.ImageStack:
+
+
+
+Added URL removal feature if the list is editable (PR #3913)
+
+Fixed ImageStack handling of visible state (PR #3834)
+
+Fixed issue (PR #4050)
+
+
+
+
+silx.gui.plot.ImageView: Fixed histogram visibility (PR #3742)
+
+
+
+silx.gui.plot.PlotWidget:
+
+
+
+
+Breaking changes:
+
+
+
+Changed add* methods return value to return the item instead of its legend (PR #3996)
+
+Refactored management of items (PR #3986, #3988)
+
+
+
+
+Added margins argument to PlotWidget.setLimits (PR #3828)
+
+
+
+Added Plotwidget.get|setDefaultColors and updated default colors behavior (PR #3835)
+
+
+
+Added PlotWidget.sigBackendChanged (PR #3890)
+
+
+
+Added per-axis zoom (PR #3842, #3843)
+
+
+
+Added support for 'other' kind of plot items (PR #3908)
+
+
+
+Added support of matplotlib tight layout as an experimental feature (PR #3865)
+
+
+
+Added support of line style defined as (offset, (dash pattern)) (PR #4020)
+
+
+
+Added support for indexed color names support (PR #3836)
+
+
+
+Added sample script to check and compare backend features (PR #4031)
+
+
+
+Changed curve default colors to matchthe one from matplotlib >=2.0 (PR #3853)
+
+
+
+Changed curve highlighting to use by default a linewidth of 2 (PR #3854)
+
+
+
+Changed plot axes tick labels behavior to use offsets (PR #4007)
+
+
+
+Changed: use the default font from mpl (PR #4025)
+
+
+
+Changed font management (PR #4047)
+
+
+
+Improved rendering for OpenGL backend (PR #4002, #4015, #4023, #4034, #4038)
+
+
+
+Fixed documentation (PR #3773)
+
+
+
+Fixed mouse cursor update (PR #3904)
+
+
+
+Fixed: do not reset zoom when changing axes scales (PR #3862, #3869)
+
+
+
+Fixed: use PlotWidget.get|setActiveScatter instead of private method (PR #3987)
+
+
+
+Fixed tick display of time series (PR #4000)
+
+
+
+Fixed matplotlib marker without background (PR #4028)
+
+
+
+
+
+silx.gui.plot.PlotWindow: Fixed display of zoom in/out actions (PR #3837)
+
+
+
+silx.gui.plot.RulerToolButton: Added interactive plot measurement tool (PR #3959, #4005)
+
+
+
+silx.gui.plot.StackView: Removed setColormap autoscale argument (PR #3805)
+
+
+
+silx.gui.plot.tools:
+
+
+
+
+silx.gui.plot.tools.PositionInfo: Fixed support of dark theme (PR #3965)
+
+
+
+silx.gui.plot.tools.profile: Fixed concurrency issue with RGB profiles (PR #3846)
+
+
+
+silx.gui.plot.tools.roi.RegionOfInterestManager:
+
+
+
+Changed interaction mode for ROI creation (PR #3978)
+
+Fixed display glitch (PR #3954)
+
+
+
+
+
+
+
+
+silx.gui.plot3d:
+
+
+
+
+Updated font management (PR #4047)
+
+
+
+Fixed deprecation warning (PR #4046)
+
+
+
+silx.gui.plot3d.ParamTreeView:
+
+
+
+Added typing and code cleanup (PR #3972)
+
+Fixed Qt6 support (PR #3971)
+
+
+
+
+
+
+silx.gui.utils.image: Added support of QImage.Format_Grayscale8 to convertQImageToArray (PR #3958)
+
+
+
+silx.gui.widgets:
+
+
+
+
+silx.gui.widgets.FloatEdit:
+
+
+
+Added widgetResizable feature (PR #4006)
+
+Added typing and code cleanup (PR #3972)
+
+
+
+
+silx.gui.widgets.StackedProgressBar: Added widget displaying more complex information progress information (PR #4008)
+
+
+
+silx.gui.plot.widgets.UrlList: Added UrlList widget (PR #3913)
+
+
+
+silx.gui.widget.UrlSelectionTable:
+
+
+
+Improved look&feel and enabled drag&drop from silx view (PR #3797)
+
+Updated: Split the URL column in 3 columns (PR #3822)
+
+Fixed exception with interaction, renamed get|setSelection to get|setUrlSelection (PR #3791)
+
+
+
+
+silx.gui.widgets.WaiterOverlay: Added a widget to display processing wheel on top of another widget (PR #3876)
+
+
+
+
+
+silx.utils:
+
+
+
+silx.utils.launcher: Improved error message (PR #3793)
+
+silx.utils.retry: Fixed: Lazy-loading of multiprocessing module (PR #3979)
+
+
+
+
+Miscellaneous
+
+
+
+
+Dependencies:
+
+
+
+Removed support of Python 3.6 (PR #3712), PySide2 (PR #3784) and fabio<0.9 (PR #3829)
+
+Replaced setuptools's pkg_resources with packaging as runtime dependency (PR #3910)
+
+Fixed support of pint >= 0.20 (PR #3725), cython (PR #3770, #4033) and PyInstaller v6 (PR #4041)
+
+Fixed deprecation warnings from numpy, scipy, matplotlib and h5py (PR #3741, #3777, #4045, #3980)
+
+
+
+
+Clean-up:
+
+
+
+Removed features deprecated since <1.0.0 (PR #3798, #3799, #3802, #3804)
+
+Removed remaining Python2 support (PR #3815, #3840, #3952)
+
+Removed unused imports (PR #3814)
+
+Replaced OrderedDict by dict (PR #3830)
+
+Updated: Using black to format the code (PR #3991)
+
+Fixed typo: 4 "" quotes instead of 3. (PR #3838)
+
+
+
+
+Build:
+
+
+
+Removed setup.py commands and options (PR #3831)
+
+Removed constraint on setuptools version (PR #3909)
+
+Updated build dependencies (PR #4035)
+
+Fixed Windows fat binary filename and links (PR #4048)
+
+Bump to 2.0.dev (PR #4014)
+
+
+
+
+Debian packaging:
+
+
+
+Removed Debian 10 and 11 packaging (PR #4017)
+
+Added Debian 12 packaging (PR #3812)
+
+Added pytest-mock to Debian build dependencies (PR #3740)
+
+Updated build-deb.sh (PR #4022, #3772) and rules (PR #3732)
+
+
+
+
+Updated documentation (PR #3765, #3899, #3970, #3994, #4037, #4036, #4039, #4042, #4055)
+
+
+
+Updated continuous integration (PR #3727, #3967, #3983)
+
+
+
+Fixed tests (PR #3722, #3723, #4043, #4044)
+
+
+
+</details>
+
+New Contributors
+
+
+
+@loichuder made their first contribution in https://github.com/silx-kit/silx/pull/3774
+
+@alejandrohomsp made their first contribution in https://github.com/silx-kit/silx/pull/3832
+
+@carez made their first contribution in https://github.com/silx-kit/silx/pull/3926
+
+@lesaintjerome made their first contribution in https://github.com/silx-kit/silx/pull/3943
+
+
+Full Changelog: https://github.com/silx-kit/silx/compare/v1.1.2...v2.0.0",api,True,findable,0.0,0.0,0.0,1.0,0.0,2024-01-30T13:54:09.000Z,2024-01-30T13:54:09.000Z,cern.zenodo,cern,,,,
+10.26302/sshade/experiment_rc_20191112_000,VIS-NIR reflectance spectra collected during low-temperature and near-vacuum sublimation of compact slabs of salty ice produced by slowly freezing solutions of MgSO4 with three different concentrations,SSHADE/BYPASS (OSUG Data Center),2023.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",Compact slabs of salty (MgSO4) ice are produced by slowly freezing small volumes of salt solutions into a laboratory freezer at 230K. The samples are then introduced in the SCITEAS-2 simulations chamber and their slow sublimation at low temperature and in secondary vacuum is followed for several tens of hours by VIS-NIR hyperspectral imaging.,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-06-09T17:17:08.000Z,2023-06-09T17:17:08.000Z,inist.sshade,mgeg,"laboratory measurement,biconical reflection,imaging,Vis,Visible,NIR,Near-Infrared,reflectance factor,water ice,Magnesium(II) sulfate hydrates,laboratory,inorganic molecular solid,sulfate","[{'subject': 'laboratory measurement', 'subjectScheme': 'main'}, {'subject': 'biconical reflection', 'subjectScheme': 'main'}, {'subject': 'imaging', 'subjectScheme': 'main'}, {'subject': 'Vis', 'subjectScheme': 'variables'}, {'subject': 'Visible', 'subjectScheme': 'variables'}, {'subject': 'NIR', 'subjectScheme': 'variables'}, {'subject': 'Near-Infrared', 'subjectScheme': 'variables'}, {'subject': 'reflectance factor', 'subjectScheme': 'variables'}, {'subject': 'water ice', 'subjectScheme': 'name'}, {'subject': 'Magnesium(II) sulfate hydrates', 'subjectScheme': 'name'}, {'subject': 'laboratory', 'subjectScheme': 'origin'}, {'subject': 'inorganic molecular solid', 'subjectScheme': 'compound type'}, {'subject': 'sulfate', 'subjectScheme': 'compound type'}]",['88 spectra'],['ASCII']
+10.26302/sshade/experiment_jg_20091028_001,"Vis-NIR reflectance spectra of Udokan (Siberia, Russia) basalt powder",SSHADE/SOSYPOL (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",Vis-NIR reflectance spectra of the Udokan basalts altered in cold and arid environment (Siberia). The samples were collected along lava flow. The experiment contains spectra of the whole-rock powders.,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2019-12-09T05:15:26.000Z,2019-12-09T05:15:26.000Z,inist.sshade,mgeg,"natural terrestrial,nesosilicate,olivine,inosilicate,pyroxenes,tektosilicate,plagioclases,phyllosilicate,smectites,silicate,iddingsite,carbonate,calcite,zeolites,oxide-hydroxide,ferrihydrite,laboratory measurement,bidirectional reflection,macroscopic,Vis,Visible,NIR,Near-Infrared,bidirectional reflectance","[{'subject': 'natural terrestrial'}, {'subject': 'nesosilicate'}, {'subject': 'olivine'}, {'subject': 'inosilicate'}, {'subject': 'pyroxenes'}, {'subject': 'tektosilicate'}, {'subject': 'plagioclases'}, {'subject': 'phyllosilicate'}, {'subject': 'smectites'}, {'subject': 'silicate'}, {'subject': 'iddingsite'}, {'subject': 'carbonate'}, {'subject': 'calcite'}, {'subject': 'zeolites'}, {'subject': 'oxide-hydroxide'}, {'subject': 'ferrihydrite'}, {'subject': 'laboratory measurement'}, {'subject': 'bidirectional reflection'}, {'subject': 'macroscopic'}, {'subject': 'Vis'}, {'subject': 'Visible'}, {'subject': 'NIR'}, {'subject': 'Near-Infrared'}, {'subject': 'bidirectional reflectance'}]",['3 spectra'],['ASCII']
+10.26302/sshade/experiment_dt_20180710_001,Br K edge XAS of gallium bromide solution in hydrothermal conditions at 300bars and between 300 and 650K,SSHADE/FAME (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","Two concentrations: Ga3+ 0.17m, Br- 0.51m and Ga3+ 0.017m, Br- 0.051m; temperature varying from 300 to 650K",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2019-12-05T09:13:23.000Z,2019-12-05T09:13:23.000Z,inist.sshade,mgeg,"laboratory,liquid solution,Gallium bromide solution in hydrothermal conditions: Ga3+ 0.17m, Br- 0.51m,Gallium bromide solution in hydrothermal conditions: Ga3+ 0.017m, Br- 0.051m,laboratory measurement,fluorescence emission,None,hard X,hard X-rays,transmission","[{'subject': 'laboratory'}, {'subject': 'liquid solution'}, {'subject': 'Gallium bromide solution in hydrothermal conditions: Ga3+ 0.17m, Br- 0.51m'}, {'subject': 'Gallium bromide solution in hydrothermal conditions: Ga3+ 0.017m, Br- 0.051m'}, {'subject': 'laboratory measurement'}, {'subject': 'fluorescence emission'}, {'subject': 'None'}, {'subject': 'hard X'}, {'subject': 'hard X-rays'}, {'subject': 'transmission'}]",['16 spectra'],['ASCII']
+10.15778/resif.zo2014,HiK-NET temporary experiment (RESIF-SISMOB),RESIF - Réseau Sismologique et géodésique Français,2011.0,en,Other,"Open Access,Creative Commons Attribution 4.0 International","HiK-NET for Himalaya Karnali Network is a temporary seismic experiment in Far Western Nepal. Goal: Monitoring the mid-crustal seismicity along the downdip end of locked fault segments of the Main Himalayan Thrust, along a 100 km stretch of the fault. Backbone: 15 seismic stations deployed for ~2 years (2014-2016) in Karnali river region (Far Western Nepal). Sensors: 8 CMG40 and 7 Le3D5s. Digitizers: Nanometrics Taurus.",mds,True,findable,0.0,0.0,0.0,1.0,0.0,2018-06-05T14:22:31.000Z,2018-06-05T14:22:31.000Z,inist.resif,vcob,"Seismology,Temporary network,Himalaya,Nepal,Main Himalayan Thrust","[{'subject': 'Seismology'}, {'subject': 'Temporary network'}, {'subject': 'Himalaya'}, {'subject': 'Nepal'}, {'subject': 'Main Himalayan Thrust'}]","['15 stations during 3 years, 289 Gb']","['Miniseed data', 'stationXML metadata']"
+10.26302/sshade/bandlist_abs_c2h2_c2h2-ii,Absorption band list of C2H2 in natural solid C2H2 (phase II),SSHADE/BANDLIST (OSUG Data Center),2023.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","NIR-MIR-FIR absorption band list of $C_2H_2$ in natural solid $C_2H_2$ (phase II) at 20 and 65 K, + 130K for FIR",mds,True,findable,0.0,0.0,8.0,0.0,0.0,2023-04-30T18:19:11.000Z,2023-04-30T18:19:12.000Z,inist.sshade,mgeg,"natural C2H2 - phase II,Ethyne,Acetylene II ice,C2H2-II,Ethyne,74-86-2,C2H2,non polar molecular solid,molecular solids with apolar molecules,organic molecular solid,absorption,FIR,MIR,NIR,band frequency,band width,band intensity,transition and vibration modes","[{'subject': 'natural C2H2 - phase II', 'subjectScheme': 'name'}, {'subject': 'Ethyne', 'subjectScheme': 'name'}, {'subject': 'Acetylene II ice', 'subjectScheme': 'name'}, {'subject': 'C2H2-II', 'subjectScheme': 'name'}, {'subject': 'Ethyne', 'subjectScheme': 'IUPAC name'}, {'subject': '74-86-2', 'subjectScheme': 'CAS number'}, {'subject': 'C2H2', 'subjectScheme': 'formula'}, {'subject': 'non polar molecular solid', 'subjectScheme': 'class'}, {'subject': 'molecular solids with apolar molecules', 'subjectScheme': 'class'}, {'subject': 'organic molecular solid', 'subjectScheme': 'compound type'}, {'subject': 'absorption', 'subjectScheme': 'var'}, {'subject': 'FIR', 'subjectScheme': 'var'}, {'subject': 'MIR', 'subjectScheme': 'var'}, {'subject': 'NIR', 'subjectScheme': 'var'}, {'subject': 'band frequency', 'subjectScheme': 'var'}, {'subject': 'band width', 'subjectScheme': 'var'}, {'subject': 'band intensity', 'subjectScheme': 'var'}, {'subject': 'transition and vibration modes', 'subjectScheme': 'var'}]",,['ASCII']
+10.5281/zenodo.10157942,X-ray diffraction images for Hen Egg White Lysozyme co-crystallized with 10mM TbXo4-NMet2 - PDB ID: 8PIW,Zenodo,2023.0,,Dataset,Creative Commons Attribution 4.0 International,"Xray diffraction images for HEWL structure co-crystallized with 10mM TbXo4-NMet2. Dataset collected at SOLEIL - Proxima 1 (PX1) beamline. For experimental details, see XDS.INP file (input file for XDS program).",api,True,findable,0.0,0.0,0.0,0.0,0.0,2024-01-18T23:44:17.000Z,2024-01-18T23:44:17.000Z,cern.zenodo,cern,,,,
+10.6084/m9.figshare.c.6604292,Predictors of changing patterns of adherence to containment measures during the early stage of COVID-19 pandemic: an international longitudinal study,figshare,2023.0,,Collection,Creative Commons Attribution 4.0 International,"Abstract Background Identifying common factors that affect public adherence to COVID-19 containment measures can directly inform the development of official public health communication strategies. The present international longitudinal study aimed to examine whether prosociality, together with other theoretically derived motivating factors (self-efficacy, perceived susceptibility and severity of COVID-19, perceived social support) predict the change in adherence to COVID-19 containment strategies. Method In wave 1 of data collection, adults from eight geographical regions completed online surveys beginning in April 2020, and wave 2 began in June and ended in September 2020. Hypothesized predictors included prosociality, self-efficacy in following COVID-19 containment measures, perceived susceptibility to COVID-19, perceived severity of COVID-19 and perceived social support. Baseline covariates included age, sex, history of COVID-19 infection and geographical regions. Participants who reported adhering to specific containment measures, including physical distancing, avoidance of non-essential travel and hand hygiene, were classified as adherence. The dependent variable was the category of adherence, which was constructed based on changes in adherence across the survey period and included four categories: non-adherence, less adherence, greater adherence and sustained adherence (which was designated as the reference category). Results In total, 2189 adult participants (82% female, 57.2% aged 31–59 years) from East Asia (217 [9.7%]), West Asia (246 [11.2%]), North and South America (131 [6.0%]), Northern Europe (600 [27.4%]), Western Europe (322 [14.7%]), Southern Europe (433 [19.8%]), Eastern Europe (148 [6.8%]) and other regions (96 [4.4%]) were analyzed. Adjusted multinomial logistic regression analyses showed that prosociality, self-efficacy, perceived susceptibility and severity of COVID-19 were significant factors affecting adherence. Participants with greater self-efficacy at wave 1 were less likely to become non-adherence at wave 2 by 26% (adjusted odds ratio [aOR], 0.74; 95% CI, 0.71 to 0.77; P &lt; .001), while those with greater prosociality at wave 1 were less likely to become less adherence at wave 2 by 23% (aOR, 0.77; 95% CI, 0.75 to 0.79; P = .04). Conclusions This study provides evidence that in addition to emphasizing the potential severity of COVID-19 and the potential susceptibility to contact with the virus, fostering self-efficacy in following containment strategies and prosociality appears to be a viable public health education or communication strategy to combat COVID-19.",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-04-18T04:38:34.000Z,2023-04-18T04:38:34.000Z,figshare.ars,otjm,"Medicine,Biotechnology,Sociology,FOS: Sociology,69999 Biological Sciences not elsewhere classified,FOS: Biological sciences,Science Policy,110309 Infectious Diseases,FOS: Health sciences","[{'subject': 'Medicine'}, {'subject': 'Biotechnology'}, {'subject': 'Sociology'}, {'subject': 'FOS: Sociology', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': '69999 Biological Sciences not elsewhere classified', 'schemeUri': 'http://www.abs.gov.au/ausstats/abs@.nsf/0/6BB427AB9696C225CA2574180004463E', 'subjectScheme': 'FOR'}, {'subject': 'FOS: Biological sciences', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': 'Science Policy'}, {'subject': '110309 Infectious Diseases', 'schemeUri': 'http://www.abs.gov.au/ausstats/abs@.nsf/0/6BB427AB9696C225CA2574180004463E', 'subjectScheme': 'FOR'}, {'subject': 'FOS: Health sciences', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}]",,
+10.5281/zenodo.10533809,SpectralGPT: The first remote sensing foundation model customized for spectral data,Zenodo,2024.0,,Dataset,Creative Commons Attribution 4.0 International,"SpectralGPT is the first purpose-built foundation model designed explicitly for spectral RS data. It considers unique characteristics of spectral data, i.e., spatial-spectral coupling and spectral sequentiality, in the MAE framework with a simple yet effective 3D GPT network.
+
+
+We will gradually release the trained models (SpectralGPT, SpectralGPT+), the new benchmark dataset (SegMunich) for the downstream task of semantic segmentation, original code, and implementation instructions.",api,True,findable,0.0,0.0,0.0,0.0,0.0,2024-01-22T02:08:21.000Z,2024-01-22T02:08:21.000Z,cern.zenodo,cern,,,,
+10.26302/sshade/experiment_lb_20210517_001,Vis-NIR reflectance spectra of a powdered and a cut section of NWA4766 (basaltic shergottite) at various observational geometries,SSHADE/ROMA+GhoSST (OSUG Data Center),2021.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",Vis-NIR reflectance spectra of a powdered and a cut section of NWA4766 (basaltic shergottite) at various observational geometries with emergence angles between -60° and 60° by steps of 10° for the powder and between -50° and 50° by steps of 10° for the cut section sample,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2021-05-19T13:59:22.000Z,2021-05-19T13:59:23.000Z,inist.sshade,mgeg,"extraterrestrial,martian,shergottite,inosilicate,pyroxene,tektosilicate,plagioclase,laboratory measurement,bidirectional reflection,macroscopic,Vis,Visible,NIR,Near-Infrared,reflectance factor","[{'subject': 'extraterrestrial'}, {'subject': 'martian'}, {'subject': 'shergottite'}, {'subject': 'inosilicate'}, {'subject': 'pyroxene'}, {'subject': 'tektosilicate'}, {'subject': 'plagioclase'}, {'subject': 'laboratory measurement'}, {'subject': 'bidirectional reflection'}, {'subject': 'macroscopic'}, {'subject': 'Vis'}, {'subject': 'Visible'}, {'subject': 'NIR'}, {'subject': 'Near-Infrared'}, {'subject': 'reflectance factor'}]",['64 spectra'],['ASCII']
+10.26302/sshade/experiment_op_20181105_002,Ni K edge XAS transmission of Ni metallic foil reference at ambient conditions,SSHADE/FAME (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2019-12-05T09:07:34.000Z,2019-12-05T09:07:34.000Z,inist.sshade,mgeg,"commercial,elemental solid,metallic Ni,laboratory measurement,transmission,None,hard X,hard X-rays","[{'subject': 'commercial'}, {'subject': 'elemental solid'}, {'subject': 'metallic Ni'}, {'subject': 'laboratory measurement'}, {'subject': 'transmission'}, {'subject': 'None'}, {'subject': 'hard X'}, {'subject': 'hard X-rays'}]",['1 spectrum'],['ASCII']
+10.26302/sshade/experiment_op_20200623_001,"Vis-NIR reflectance spectra of a mixture of Magnetite, NH4-Nontronite, Antigonite and Dolomite, pure, mixed with Water ice, during and after ice sublimation",SSHADE/CSS (OSUG Data Center),2020.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","This mixture was prepared as a spectral analogue for Ceres surface material. We measured the reflectance spectra (from 0.5 to 4 µm) of the mixture pure (at room temperature) and mixed with water ice particles (at 173 K), as well as during and after sublimation of the water ice under high vacuum (at 173 K). The spectrum of the surface obtained after sublimation exhibits a blue spectral slope.",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2020-11-02T12:56:44.000Z,2020-11-02T15:55:13.000Z,inist.sshade,mgeg,"mineral,natural terrestrial,oxide-hydroxide,Magnetite,laboratory,phyllosilicate,NH4-nontronite,Antigorite,carbonate,Dolomite,interlayer phase,interlayer water,solid,inorganic molecular solid,water ice,commercial,unknown,Unknown black coating of Matt Black Aluminum Foil Tape Advance Gaffa®,laboratory measurement,bidirectional reflection,macroscopic,Vis,Visible,NIR,Near-Infrared,reflectance factor","[{'subject': 'mineral'}, {'subject': 'natural terrestrial'}, {'subject': 'oxide-hydroxide'}, {'subject': 'Magnetite'}, {'subject': 'laboratory'}, {'subject': 'phyllosilicate'}, {'subject': 'NH4-nontronite'}, {'subject': 'Antigorite'}, {'subject': 'carbonate'}, {'subject': 'Dolomite'}, {'subject': 'interlayer phase'}, {'subject': 'interlayer water'}, {'subject': 'solid'}, {'subject': 'inorganic molecular solid'}, {'subject': 'water ice'}, {'subject': 'commercial'}, {'subject': 'unknown'}, {'subject': 'Unknown black coating of Matt Black Aluminum Foil Tape Advance Gaffa®'}, {'subject': 'laboratory measurement'}, {'subject': 'bidirectional reflection'}, {'subject': 'macroscopic'}, {'subject': 'Vis'}, {'subject': 'Visible'}, {'subject': 'NIR'}, {'subject': 'Near-Infrared'}, {'subject': 'reflectance factor'}]",['26 spectra'],['ASCII']
+10.15778/resif.xq2020,"CHAUVET temporary experiment for study on seismic hazards applied to the Chauvet Cave, France (RESIF-SISMOB)",RESIF - Réseau Sismologique et géodésique Français,2024.0,,Dataset,,"The Chauvet Cave (Ardèche), discovered in 1994, is characterised by its cave art, which is among the oldest images of mankind, by its numerous palaeontological remains and by its remarkable state of preservation. It has been condemned to the public since its discovery for preservation. However, this stable state of preservation is linked to the climatological regulation of the scree that closes the entrance to the prehistoric porch. It seems to be settling down and another stage of the cliff's collapse remains to be assessed with the analysis of the stability of the Pillar of Abraham.The epicenter of the Le Teil earthquake 2019 is located at the northeastern part of the Cévennes fault system and the Chauvet cave sits in the immediate vicinity of the southwestern part of this active fault system. Within the framework of the programme funded by AURA PAI, the main aim is to monitor and define the vulnerabilities of the entrance area to the Chauvet cave and more specifically to analyse the response of the pilar evolution to climatic and seismic triggers.",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2022-03-15T16:00:25.000Z,2022-03-15T16:01:51.000Z,inist.resif,vcob,"Heritage,Risk,Earthquake,RockSlide,Cave","[{'subject': 'Heritage'}, {'subject': 'Risk'}, {'subject': 'Earthquake'}, {'subject': 'RockSlide'}, {'subject': 'Cave'}]","['3 stations, 46Go (miniseed format)']","['Miniseed data', 'stationXML metadata']"
+10.26302/sshade/experiment_bs_20191230_001,"Near-IR bidirectional reflection spectra (i=0-70°/e=0-70°/az=180°) of Volcanic tuff (50-100 µm grains) at 263K, Patm",SSHADE/GhoSST (OSUG Data Center),2019.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",NIR bidirectional reflection spectra (i=0-70°/e=0-70°/az=180°) of Volcanic tuff (2µm grains) at 263K and ambient pressure,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2019-12-30T09:46:18.000Z,2019-12-30T09:46:19.000Z,inist.sshade,mgeg,"mineral,natural terrestrial,tektosilicate,Anorthite,Albite,Orthoclase,Nepheline,inosilicate,Diopside,nesosilicate,Forsterite,oxide-hydroxide,Hematite,Ilmenite,physically adsorbed phase,adsorbed H2O,laboratory measurement,bidirectional reflection,macroscopic,Vis,Visible,NIR,Near-Infrared,reflectance factor","[{'subject': 'mineral'}, {'subject': 'natural terrestrial'}, {'subject': 'tektosilicate'}, {'subject': 'Anorthite'}, {'subject': 'Albite'}, {'subject': 'Orthoclase'}, {'subject': 'Nepheline'}, {'subject': 'inosilicate'}, {'subject': 'Diopside'}, {'subject': 'nesosilicate'}, {'subject': 'Forsterite'}, {'subject': 'oxide-hydroxide'}, {'subject': 'Hematite'}, {'subject': 'Ilmenite'}, {'subject': 'physically adsorbed phase'}, {'subject': 'adsorbed H2O'}, {'subject': 'laboratory measurement'}, {'subject': 'bidirectional reflection'}, {'subject': 'macroscopic'}, {'subject': 'Vis'}, {'subject': 'Visible'}, {'subject': 'NIR'}, {'subject': 'Near-Infrared'}, {'subject': 'reflectance factor'}]",['1 spectrum'],['ASCII']
+10.6084/m9.figshare.22599661,Additional file 1 of Procalcitonin to reduce exposure to antibiotics and individualise treatment in hospitalised old patients with pneumonia: a randomised study,figshare,2023.0,,Text,Creative Commons Attribution 4.0 International,Additional file 1.,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-04-13T09:42:54.000Z,2023-04-13T09:42:55.000Z,figshare.ars,otjm,"Space Science,Medicine,Immunology,FOS: Clinical medicine,Cancer,111714 Mental Health,FOS: Health sciences,110309 Infectious Diseases","[{'subject': 'Space Science'}, {'subject': 'Medicine'}, {'subject': 'Immunology'}, {'subject': 'FOS: Clinical medicine', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': 'Cancer'}, {'subject': '111714 Mental Health', 'schemeUri': 'http://www.abs.gov.au/ausstats/abs@.nsf/0/6BB427AB9696C225CA2574180004463E', 'subjectScheme': 'FOR'}, {'subject': 'FOS: Health sciences', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': '110309 Infectious Diseases', 'schemeUri': 'http://www.abs.gov.au/ausstats/abs@.nsf/0/6BB427AB9696C225CA2574180004463E', 'subjectScheme': 'FOR'}]",['317731 Bytes'],
+10.26302/sshade/experiment_lb_20170719_001,"Mid-IR absorbance spectra of bulk CI chondrites in KBr pellets at ambient temperature, 150°C and 300°C",SSHADE/GhoSST (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","Mid-IR absorbance spectra of 2 bulk CI chondrites, Orgueil and Ivuna, in KBr pellets at 3 different temperatures: ambient temperature, 150°C and 300°C",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2020-02-11T14:20:21.000Z,2020-02-11T14:20:21.000Z,inist.sshade,mgeg,"extraterrestrial,complex organic-mineral mix,bulk Orgueil,physically adsorbed phase,adsorbed water on Orgueil bulk,commercial,bromide,KBr,adsorbed water on KBr (Beck14),matrix Orgueil heated at 150C,matrix Orgueil heated at 300C,adsorbed water on Ivuna bulk,matrix Ivuna heated at 300C,laboratory measurement,transmission,macroscopic,MIR,Mid-Infrared,absorbance","[{'subject': 'extraterrestrial'}, {'subject': 'complex organic-mineral mix'}, {'subject': 'bulk Orgueil'}, {'subject': 'physically adsorbed phase'}, {'subject': 'adsorbed water on Orgueil bulk'}, {'subject': 'commercial'}, {'subject': 'bromide'}, {'subject': 'KBr'}, {'subject': 'adsorbed water on KBr (Beck14)'}, {'subject': 'matrix Orgueil heated at 150C'}, {'subject': 'matrix Orgueil heated at 300C'}, {'subject': 'adsorbed water on Ivuna bulk'}, {'subject': 'matrix Ivuna heated at 300C'}, {'subject': 'laboratory measurement'}, {'subject': 'transmission'}, {'subject': 'macroscopic'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'absorbance'}]",['6 spectra'],['ASCII']
+10.26302/sshade/experiment_ik_20180419_001,Co K edge XAS transmission of Co metallic foil reference at ambient conditions,SSHADE/FAME (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2019-12-05T09:00:05.000Z,2019-12-05T09:00:10.000Z,inist.sshade,mgeg,"commercial,elemental solid,metallic Co,laboratory measurement,transmission,None,hard X,hard X-rays","[{'subject': 'commercial'}, {'subject': 'elemental solid'}, {'subject': 'metallic Co'}, {'subject': 'laboratory measurement'}, {'subject': 'transmission'}, {'subject': 'None'}, {'subject': 'hard X'}, {'subject': 'hard X-rays'}]",['1 spectrum'],['ASCII']
+10.26302/sshade/experiment_bms_20150101_003,VUV absorbance spectra between 10 and 130 K of amorphous CH3CH2CH2CN deposited at 10 K,SSHADE/ACID (OSUG Data Center),2019.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",VUV absorbance spectra between 10 and 130 K of amorphous CH3CH2CH2CN deposited at 10 K,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2021-03-01T20:13:18.000Z,2021-03-01T20:13:20.000Z,inist.sshade,mgeg,"laboratory,organic molecular solid,amorphous CH3CH2CH2CN ice,laboratory measurement,transmission,macroscopic,VUV,Vacuum Ultraviolet,absorbance","[{'subject': 'laboratory'}, {'subject': 'organic molecular solid'}, {'subject': 'amorphous CH3CH2CH2CN ice'}, {'subject': 'laboratory measurement'}, {'subject': 'transmission'}, {'subject': 'macroscopic'}, {'subject': 'VUV'}, {'subject': 'Vacuum Ultraviolet'}, {'subject': 'absorbance'}]",['4 spectra'],['ASCII']
+10.26302/sshade/experiment_bs_20191230_011,"Near-IR bidirectional reflection spectra (i=0°, e=30°) of Volcanic tuff for 9 different grain sizes at 298K in ambient air",SSHADE/GhoSST (OSUG Data Center),2019.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","Near-IR bidirectional reflection spectra (i=0°, e=30°) of Volcanic tuff for different grain sizes (&lt;25, 25-50, 50-100, 100-200, 200-280, 280-400, 400-560, 560-800, 800-1120 µm) at 298K in ambient air",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2019-12-30T14:55:28.000Z,2019-12-30T14:55:28.000Z,inist.sshade,mgeg,"mineral,natural terrestrial,tektosilicate,Anorthite,Albite,Orthoclase,Nepheline,inosilicate,Diopside,nesosilicate,Forsterite,oxide-hydroxide,Hematite,Ilmenite,physically adsorbed phase,adsorbed H2O,laboratory measurement,bidirectional reflection,macroscopic,NIR,Near-Infrared,reflectance factor","[{'subject': 'mineral'}, {'subject': 'natural terrestrial'}, {'subject': 'tektosilicate'}, {'subject': 'Anorthite'}, {'subject': 'Albite'}, {'subject': 'Orthoclase'}, {'subject': 'Nepheline'}, {'subject': 'inosilicate'}, {'subject': 'Diopside'}, {'subject': 'nesosilicate'}, {'subject': 'Forsterite'}, {'subject': 'oxide-hydroxide'}, {'subject': 'Hematite'}, {'subject': 'Ilmenite'}, {'subject': 'physically adsorbed phase'}, {'subject': 'adsorbed H2O'}, {'subject': 'laboratory measurement'}, {'subject': 'bidirectional reflection'}, {'subject': 'macroscopic'}, {'subject': 'NIR'}, {'subject': 'Near-Infrared'}, {'subject': 'reflectance factor'}]",['9 spectra'],['ASCII']
+10.26302/sshade/experiment_op_20201223_001,"Vis-NIR reflectance spectra of H2O ice with varying grain sizes (70-1060µm), shapes (spherical or irregular) and three mixtures, from 70 to 220 K",SSHADE/CSS (OSUG Data Center),2021.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","We measured the reflectance spectra (from 0.4 to 4.2 µm) of water ice particles of varying sizes (from 70 to 1060 µm), shapes (spherical or irregular grains), and three mixtures of ~70 and ~1060 µm grains, at different temperatures from 70 to 220 K.",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2021-11-26T18:12:39.000Z,2021-11-26T18:12:40.000Z,inist.sshade,mgeg,"solid,laboratory,inorganic molecular solid,water ice,laboratory measurement,bidirectional reflection,macroscopic,Vis,Visible,NIR,Near-Infrared,reflectance factor","[{'subject': 'solid'}, {'subject': 'laboratory'}, {'subject': 'inorganic molecular solid'}, {'subject': 'water ice'}, {'subject': 'laboratory measurement'}, {'subject': 'bidirectional reflection'}, {'subject': 'macroscopic'}, {'subject': 'Vis'}, {'subject': 'Visible'}, {'subject': 'NIR'}, {'subject': 'Near-Infrared'}, {'subject': 'reflectance factor'}]",['75 spectra'],['ASCII']
+10.26302/sshade/experiment_sp_20210420_1000,Vis-NIR reflectance spectroscopy of the meteorite Murchison with varying grain sizes from 1000µm to 45µm,SSHADE/CHIPS (OSUG Data Center),2021.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","0.35 to 2.5µm reflectance spectroscopy of a powdered sample of the meteorite Murchison sieved to select grains sizes &lt;1000µm, &lt;500µm, &lt;250µm, &lt;150µm, &lt;90µm and &lt;45µm.",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2021-04-22T14:45:05.000Z,2021-04-22T14:45:07.000Z,inist.sshade,mgeg,"extraterrestrial,carbonaceous chondrite,CM,complex organic-mineral mix,matrix Murchison,complex mineral mix,chondrules Murchison,CAIs Murchison,laboratory measurement,bidirectional reflection,macroscopic,Vis,Visible,NIR,Near-Infrared,reflectance factor","[{'subject': 'extraterrestrial'}, {'subject': 'carbonaceous chondrite'}, {'subject': 'CM'}, {'subject': 'complex organic-mineral mix'}, {'subject': 'matrix Murchison'}, {'subject': 'complex mineral mix'}, {'subject': 'chondrules Murchison'}, {'subject': 'CAIs Murchison'}, {'subject': 'laboratory measurement'}, {'subject': 'bidirectional reflection'}, {'subject': 'macroscopic'}, {'subject': 'Vis'}, {'subject': 'Visible'}, {'subject': 'NIR'}, {'subject': 'Near-Infrared'}, {'subject': 'reflectance factor'}]",['6 spectra'],['ASCII']
+10.15778/resif.yt2001,2001 WEST KUNLUN Broadband and short period temporary experiment (RESIF - SISMOB),RESIF - Réseau Sismologique et géodésique Français,2001.0,en,Other,"Open Access,Creative Commons Attribution 4.0 International",WEST KUNLUN Broadband and short period temporary experiment (RESIF - SISMOB),mds,True,findable,0.0,0.0,0.0,1.0,0.0,2018-04-27T07:17:42.000Z,2018-04-27T07:17:42.000Z,inist.resif,vcob,"Seismology,Tibet,China,Kunlun","[{'subject': 'Seismology'}, {'subject': 'Tibet'}, {'subject': 'China'}, {'subject': 'Kunlun'}]",['37 Gb;50 stations'],['SEED data']
+10.26302/sshade/experiment_zed_20230921_01,MIR Average reflectance spectra of eight Ryugu fragments (chambers A and C),SSHADE/DAYSY (OSUG Data Center),2023.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",MIR spectroscopy average reflectance spectra of eight Ryugu micrometrique fragments collected at different angles,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-09-21T11:54:24.000Z,2023-09-21T11:54:24.000Z,inist.sshade,mgeg,"laboratory measurement,transmission,micro-imaging,MIR,Mid-Infrared,reflectance factor,Bulk chamber A Ryugu samples,Bulk Chamber C Ryugu samples,extraterrestrial,planetary,complex organic-mineral mix","[{'subject': 'laboratory measurement', 'subjectScheme': 'main'}, {'subject': 'transmission', 'subjectScheme': 'main'}, {'subject': 'micro-imaging', 'subjectScheme': 'main'}, {'subject': 'MIR', 'subjectScheme': 'variables'}, {'subject': 'Mid-Infrared', 'subjectScheme': 'variables'}, {'subject': 'reflectance factor', 'subjectScheme': 'variables'}, {'subject': 'Bulk chamber A Ryugu samples', 'subjectScheme': 'name'}, {'subject': 'Bulk Chamber C Ryugu samples', 'subjectScheme': 'name'}, {'subject': 'extraterrestrial', 'subjectScheme': 'family'}, {'subject': 'planetary', 'subjectScheme': 'origin'}, {'subject': 'complex organic-mineral mix', 'subjectScheme': 'compound type'}]",['8 spectra'],['ASCII']
+10.26302/sshade/experiment_mb_20230522_0001,VNIR and SWIR spectra of terrestrial feldspathic rocks and powders (sample NR1 as an example),SSHADE/Mirabelle (OSUG Data Center),2023.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",Visible Near-Infrared spectra.,mds,True,findable,0.0,0.0,0.0,1.0,0.0,2023-07-06T21:46:50.000Z,2023-07-06T21:46:51.000Z,inist.sshade,mgeg,"laboratory measurement,biconical reflection,macroscopic,bidirectional reflection,imaging,Vis,Visible,NIR,Near-Infrared,reflectance factor,Plagioclases,Alkali feldspars,Amphibole,Biotite,Orthoclase,Quartz,Calcite,Epidote,Pyroxene,Olivine,Oxides,Clinopyroxene,Volcanic glass,solid,natural terrestrial,tektosilicate,inosilicate,phyllosilicate,carbonate,sorosilicate,nesosilicate,oxide-hydroxide","[{'subject': 'laboratory measurement', 'subjectScheme': 'main'}, {'subject': 'biconical reflection', 'subjectScheme': 'main'}, {'subject': 'macroscopic', 'subjectScheme': 'main'}, {'subject': 'bidirectional reflection', 'subjectScheme': 'main'}, {'subject': 'imaging', 'subjectScheme': 'main'}, {'subject': 'Vis', 'subjectScheme': 'variables'}, {'subject': 'Visible', 'subjectScheme': 'variables'}, {'subject': 'NIR', 'subjectScheme': 'variables'}, {'subject': 'Near-Infrared', 'subjectScheme': 'variables'}, {'subject': 'reflectance factor', 'subjectScheme': 'variables'}, {'subject': 'Plagioclases', 'subjectScheme': 'name'}, {'subject': 'Alkali feldspars', 'subjectScheme': 'name'}, {'subject': 'Amphibole', 'subjectScheme': 'name'}, {'subject': 'Biotite', 'subjectScheme': 'name'}, {'subject': 'Orthoclase', 'subjectScheme': 'name'}, {'subject': 'Quartz', 'subjectScheme': 'name'}, {'subject': 'Calcite', 'subjectScheme': 'name'}, {'subject': 'Epidote', 'subjectScheme': 'name'}, {'subject': 'Pyroxene', 'subjectScheme': 'name'}, {'subject': 'Olivine', 'subjectScheme': 'name'}, {'subject': 'Oxides', 'subjectScheme': 'name'}, {'subject': 'Clinopyroxene', 'subjectScheme': 'name'}, {'subject': 'Volcanic glass', 'subjectScheme': 'name'}, {'subject': 'solid', 'subjectScheme': 'family'}, {'subject': 'natural terrestrial', 'subjectScheme': 'origin'}, {'subject': 'tektosilicate', 'subjectScheme': 'compound type'}, {'subject': 'inosilicate', 'subjectScheme': 'compound type'}, {'subject': 'phyllosilicate', 'subjectScheme': 'compound type'}, {'subject': 'carbonate', 'subjectScheme': 'compound type'}, {'subject': 'sorosilicate', 'subjectScheme': 'compound type'}, {'subject': 'nesosilicate', 'subjectScheme': 'compound type'}, {'subject': 'oxide-hydroxide', 'subjectScheme': 'compound type'}]",['56 spectra'],['ASCII']
+10.15778/resif.y22014,SAFE-CO2 temporary experiment,RESIF - Réseau Sismologique et géodésique Français,2014.0,en,Dataset,"Open Access,Creative Commons Attribution 4.0 International","NORSAR has rented 12 seismic stations from SISMOB for a period of 6 months, which were installed in Adventdalen (Spitsberg, Norway) between the 6th and the 16th of May 2014. The objective was to cover an area around the CO2 lab and record the ambient seismic noise during a water injection planned for August 2014. Six of the sensors are CMG 40 (Guralp, 60 s-50 Hz), six are Noemax (Agecodagis, 20 s-50 Hz). Taurus digitizers were employed with a sampling frequency of 100 Hz. At the time of the installation the Adventdalen river was still frozen, allowing to reach its northern side using a track vehicle. Most of the stations were installed on large blocks of rock (sandstone), in some cases requiring an additional cement base. Most of the stations recorded during the whole installation period; however, station STN04 stopped recording in the middle of June, station STN08 had problems recording continuous data starting middle of July (but was being repaired middle of August) and station STN10 did not record data apart from a very short period.",mds,True,findable,0.0,0.0,0.0,2.0,0.0,2018-03-01T15:25:32.000Z,2018-03-01T15:25:32.000Z,inist.resif,vcob,"Seismology,Spitzberg","[{'subject': 'Seismology'}, {'subject': 'Spitzberg'}]",['57 Gb;12 stations'],"['miniseed data', 'stationXML metadata']"
+10.26302/sshade/experiment_op_20180717_001,Cu K edge XAS HERFD (Kalpha1) of CuO at ambient conditions,SSHADE/FAME (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2019-12-05T13:45:46.000Z,2019-12-05T13:45:47.000Z,inist.sshade,mgeg,"solid,commercial,non-oxide ceramic,BN powder,laboratory,oxide-hydroxide,CuO,laboratory measurement,fluorescence emission,None,hard X,hard X-rays","[{'subject': 'solid'}, {'subject': 'commercial'}, {'subject': 'non-oxide ceramic'}, {'subject': 'BN powder'}, {'subject': 'laboratory'}, {'subject': 'oxide-hydroxide'}, {'subject': 'CuO'}, {'subject': 'laboratory measurement'}, {'subject': 'fluorescence emission'}, {'subject': 'None'}, {'subject': 'hard X'}, {'subject': 'hard X-rays'}]",['1 spectrum'],['ASCII']
+10.26302/sshade/experiment_gs_20170713_003,Ag K edge XAS transmission of Ag2CO3,SSHADE/FAME (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2019-12-05T13:51:19.000Z,2019-12-05T13:51:19.000Z,inist.sshade,mgeg,"solid,commercial,non-oxide ceramic,BN powder,carbonate,AgCl,laboratory measurement,transmission,None,hard X","[{'subject': 'solid'}, {'subject': 'commercial'}, {'subject': 'non-oxide ceramic'}, {'subject': 'BN powder'}, {'subject': 'carbonate'}, {'subject': 'AgCl'}, {'subject': 'laboratory measurement'}, {'subject': 'transmission'}, {'subject': 'None'}, {'subject': 'hard X'}]",['1 spectrum'],['ASCII']
+10.26302/sshade/experiment_ak_20141110_1,Mid-infrared attenuated total reflectance experiment with K+ exchanged less 1 μm size fraction of beidellite (SbCa-1) equilibrated with D2O vapor under variable relative humidity,SSHADE/LSD (OSUG Data Center),2019.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2022-11-04T08:13:57.000Z,2022-11-04T08:13:58.000Z,inist.sshade,mgeg,"natural terrestrial,phyllosilicate,K-exchanged beidellite SbCa-1 size-fraction &lt;1 µm,liquid,D2O 99.9 Sigma-Aldrich,laboratory measurement,ATReflection,macroscopic,MIR,Mid-Infrared,corrected ATR absorbance","[{'subject': 'natural terrestrial'}, {'subject': 'phyllosilicate'}, {'subject': 'K-exchanged beidellite SbCa-1 size-fraction &lt;1 µm'}, {'subject': 'liquid'}, {'subject': 'D2O 99.9 Sigma-Aldrich'}, {'subject': 'laboratory measurement'}, {'subject': 'ATReflection'}, {'subject': 'macroscopic'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'corrected ATR absorbance'}]",['5 spectra'],['ASCII']
+10.26302/sshade/bandlist_raman_kutnohorite,Raman bandlist of natural Kutnohorite,SSHADE/BANDLIST (OSUG Data Center),2023.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",MIR-FIR Raman bandlist of natural Kutnohorite at 295K,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-09-02T14:28:51.000Z,2023-09-02T14:28:52.000Z,inist.sshade,mgeg,"Kutnohorite,Calcium cation,Manganese(II) cation,Magnesium(II) cation,Carbonate anion,Calcium(2+) cation,Manganese(2+) cation,Magnesium(2+) cation,14127-61-8,16397-91-4,22537-22-0,Ca2+,Mn2+,Mg2+,(CO3)2-,CaMn2+(CO3)2,Kutnohorite,non-silicate mineral,carbonate,carbonates, nitrates, borates,anhydrous carbonates,Dolomite group (Trigonal: R-3),14.02.01.03,05.AB.10,Raman scattering,FIR,MIR,band frequency,band width,band intensity,transition and vibration modes","[{'subject': 'Kutnohorite', 'subjectScheme': 'name'}, {'subject': 'Calcium cation', 'subjectScheme': 'name'}, {'subject': 'Manganese(II) cation', 'subjectScheme': 'name'}, {'subject': 'Magnesium(II) cation', 'subjectScheme': 'name'}, {'subject': 'Carbonate anion', 'subjectScheme': 'name'}, {'subject': 'Calcium(2+) cation', 'subjectScheme': 'IUPAC name'}, {'subject': 'Manganese(2+) cation', 'subjectScheme': 'IUPAC name'}, {'subject': 'Magnesium(2+) cation', 'subjectScheme': 'IUPAC name'}, {'subject': '14127-61-8', 'subjectScheme': 'CAS number'}, {'subject': '16397-91-4', 'subjectScheme': 'CAS number'}, {'subject': '22537-22-0', 'subjectScheme': 'CAS number'}, {'subject': 'Ca2+', 'subjectScheme': 'formula'}, {'subject': 'Mn2+', 'subjectScheme': 'formula'}, {'subject': 'Mg2+', 'subjectScheme': 'formula'}, {'subject': '(CO3)2-', 'subjectScheme': 'formula'}, {'subject': 'CaMn2+(CO3)2', 'subjectScheme': 'formula'}, {'subject': 'Kutnohorite', 'subjectScheme': 'IMA name'}, {'subject': 'non-silicate mineral', 'subjectScheme': 'mineral class'}, {'subject': 'carbonate', 'subjectScheme': 'compound type'}, {'subject': 'carbonates, nitrates, borates', 'subjectScheme': 'Dana class'}, {'subject': 'anhydrous carbonates', 'subjectScheme': 'Dana class'}, {'subject': 'Dolomite group (Trigonal: R-3)', 'subjectScheme': 'Dana group'}, {'subject': '14.02.01.03', 'subjectScheme': 'Dana code'}, {'subject': '05.AB.10', 'subjectScheme': 'Strunz code'}, {'subject': 'Raman scattering', 'subjectScheme': 'variables'}, {'subject': 'FIR', 'subjectScheme': 'variables'}, {'subject': 'MIR', 'subjectScheme': 'variables'}, {'subject': 'band frequency', 'subjectScheme': 'variables'}, {'subject': 'band width', 'subjectScheme': 'variables'}, {'subject': 'band intensity', 'subjectScheme': 'variables'}, {'subject': 'transition and vibration modes', 'subjectScheme': 'variables'}]",,['ASCII']
+10.26302/sshade/experiment_lb_20170731_001,"Raw, normalized and baseline-corrected of MIR transmission spectra of MET00426 matrix grains pressed on diamonds under vacuum at ambiant temperature and 300C",SSHADE/GhoSST (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","MIR spectra of several matrix grains of MET00426 at different temperature, under vacuum",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2020-10-02T09:40:50.000Z,2020-10-02T09:40:51.000Z,inist.sshade,mgeg,"extraterrestrial,complex organic-mineral mix,matrix MET00426,physically adsorbed phase,adsorbed water,matrix MET00426 heated at 300°C,laboratory measurement,transmission,microscopy,MIR,Mid-Infrared,absorbance","[{'subject': 'extraterrestrial'}, {'subject': 'complex organic-mineral mix'}, {'subject': 'matrix MET00426'}, {'subject': 'physically adsorbed phase'}, {'subject': 'adsorbed water'}, {'subject': 'matrix MET00426 heated at 300°C'}, {'subject': 'laboratory measurement'}, {'subject': 'transmission'}, {'subject': 'microscopy'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'absorbance'}]",['18 spectra'],['ASCII']
+10.26302/sshade/experiment_jg_20090301_001,"Vis-NIR reflectance spectra of Werder (Ogaden, Ethiopia) basalt",SSHADE/SOSYPOL (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","Vis-NIR reflectance spectra of the Werder (Ogaden, Ethiopia) basalts altered in hot conditions with globally increasing aridity since Late Oligocene. The samples are cobble fragments sampled from the same outcrop. The experiment contains spectra of the surface of the alteration rind and of the internal part of the samples.",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2019-12-09T05:12:18.000Z,2019-12-09T05:12:18.000Z,inist.sshade,mgeg,"natural terrestrial,nesosilicate,olivine,inosilicate,pyroxenes,tektosilicate,plagioclases,phyllosilicate,smectites,silicate,iddingsite,carbonate,calcite,laboratory measurement,bidirectional reflection,macroscopic,Vis,Visible,NIR,Near-Infrared,bidirectional reflectance","[{'subject': 'natural terrestrial'}, {'subject': 'nesosilicate'}, {'subject': 'olivine'}, {'subject': 'inosilicate'}, {'subject': 'pyroxenes'}, {'subject': 'tektosilicate'}, {'subject': 'plagioclases'}, {'subject': 'phyllosilicate'}, {'subject': 'smectites'}, {'subject': 'silicate'}, {'subject': 'iddingsite'}, {'subject': 'carbonate'}, {'subject': 'calcite'}, {'subject': 'laboratory measurement'}, {'subject': 'bidirectional reflection'}, {'subject': 'macroscopic'}, {'subject': 'Vis'}, {'subject': 'Visible'}, {'subject': 'NIR'}, {'subject': 'Near-Infrared'}, {'subject': 'bidirectional reflectance'}]",['50 spectra'],['ASCII']
+10.26302/sshade/experiment_bs_20130125_002,MIR optical constants of amorphous H2S at 56K,SSHADE/GhoSST (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",MIR optical constants of amorphous H2S from sample deposited and measured at 56K,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2020-02-01T13:55:43.000Z,2020-02-01T13:55:44.000Z,inist.sshade,mgeg,"laboratory,inorganic molecular solid,H2S amorphous,laboratory measurement,transmission,macroscopic,MIR,Mid-Infrared,optical constants","[{'subject': 'laboratory'}, {'subject': 'inorganic molecular solid'}, {'subject': 'H2S amorphous'}, {'subject': 'laboratory measurement'}, {'subject': 'transmission'}, {'subject': 'macroscopic'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'optical constants'}]",['1 spectrum'],['ASCII']
+10.26302/sshade/experiment_zed_20230524_01,Vis-NIR reflectance spectra of 14 stratospheric IDPs particles,SSHADE/DAYSY (OSUG Data Center),2023.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",Vis-NIR spectroscopy of 14 stratospheric IDPs in reflectance.,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-06-22T10:07:46.000Z,2023-06-22T10:07:47.000Z,inist.sshade,mgeg,"laboratory measurement,bidirectional reflection,microscopy,Vis,Visible,NIR,Near-Infrared,normalized reflectance,Olivine,Pyroxene,extraterrestrial,nesosilicate,inosilicate,chondritic,None","[{'subject': 'laboratory measurement', 'subjectScheme': 'main'}, {'subject': 'bidirectional reflection', 'subjectScheme': 'main'}, {'subject': 'microscopy', 'subjectScheme': 'main'}, {'subject': 'Vis', 'subjectScheme': 'variables'}, {'subject': 'Visible', 'subjectScheme': 'variables'}, {'subject': 'NIR', 'subjectScheme': 'variables'}, {'subject': 'Near-Infrared', 'subjectScheme': 'variables'}, {'subject': 'normalized reflectance', 'subjectScheme': 'variables'}, {'subject': 'Olivine', 'subjectScheme': 'name'}, {'subject': 'Pyroxene', 'subjectScheme': 'name'}, {'subject': 'extraterrestrial', 'subjectScheme': 'family'}, {'subject': 'nesosilicate', 'subjectScheme': 'compound type'}, {'subject': 'inosilicate', 'subjectScheme': 'compound type'}, {'subject': 'chondritic', 'subjectScheme': 'meteorite group'}, {'subject': 'None', 'subjectScheme': 'meteorite class'}]",['14 spectra'],['ASCII']
+10.26302/sshade/experiment_lb_20170725_001,"Mid-IR absorbance spectra of bulk CR chondrites in KBr pellets at ambient temperature, 150°C and 300°C",SSHADE/GhoSST (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","Mid-IR absorbance spectra of 6 bulk CR chondrites (GRA06100, GRO03116, GRO95577, LAP02342, RBT04133, PCA91082) in KBr pellets at 3 different temperatures: ambient temperature, 150°C and 300°C",mds,True,findable,0.0,0.0,0.0,1.0,0.0,2020-03-18T17:13:47.000Z,2020-03-18T17:13:48.000Z,inist.sshade,mgeg,"extraterrestrial,complex organic-mineral mix,matrix GRO03116,complex mineral mix,chondrules GRO03116,CAIs GRO03116,physically adsorbed phase,adsorbed water on GRO03116 bulk,commercial,bromide,KBr,adsorbed water on KBr (Beck14),matrix GRO03116 heated at 150C,matrix GRO03116 heated at 300C,matrix LAP02342,chondrules LAP02342,CAIs LAP02342,adsorbed water on LAP02342 bulk,matrix LAP02342 heated at 150C,matrix LAP02342 heated at 300C,matrix RBT04133,chondrules RBT04133,CAIs RBT04133,adsorbed water on RBT04133 bulk,matrix RBT04133 heated at 150C,matrix GRA06100,chondrules GRA06100,CAIs GRA06100,adsorbed water on GRA06100 bulk,matrix GRA06100 heated at 150C,matrix GRA06100 heated at 300C,matrix PCA91082,chondrules PCA91082,CAIs PCA91082,adsorbed water on PCA91082 bulk,matrix PCA91082 heated at 150C,matrix PCA91082 heated at 300C,matrix GRO95577 heated at 150C,chondrules GRO95577,CAIs GRO95577,adsorbed water on GRO95577 bulk,matrix GRO95577 heated at 300C,laboratory measurement,transmission,macroscopic,MIR,Mid-Infrared,absorbance","[{'subject': 'extraterrestrial'}, {'subject': 'complex organic-mineral mix'}, {'subject': 'matrix GRO03116'}, {'subject': 'complex mineral mix'}, {'subject': 'chondrules GRO03116'}, {'subject': 'CAIs GRO03116'}, {'subject': 'physically adsorbed phase'}, {'subject': 'adsorbed water on GRO03116 bulk'}, {'subject': 'commercial'}, {'subject': 'bromide'}, {'subject': 'KBr'}, {'subject': 'adsorbed water on KBr (Beck14)'}, {'subject': 'matrix GRO03116 heated at 150C'}, {'subject': 'matrix GRO03116 heated at 300C'}, {'subject': 'matrix LAP02342'}, {'subject': 'chondrules LAP02342'}, {'subject': 'CAIs LAP02342'}, {'subject': 'adsorbed water on LAP02342 bulk'}, {'subject': 'matrix LAP02342 heated at 150C'}, {'subject': 'matrix LAP02342 heated at 300C'}, {'subject': 'matrix RBT04133'}, {'subject': 'chondrules RBT04133'}, {'subject': 'CAIs RBT04133'}, {'subject': 'adsorbed water on RBT04133 bulk'}, {'subject': 'matrix RBT04133 heated at 150C'}, {'subject': 'matrix GRA06100'}, {'subject': 'chondrules GRA06100'}, {'subject': 'CAIs GRA06100'}, {'subject': 'adsorbed water on GRA06100 bulk'}, {'subject': 'matrix GRA06100 heated at 150C'}, {'subject': 'matrix GRA06100 heated at 300C'}, {'subject': 'matrix PCA91082'}, {'subject': 'chondrules PCA91082'}, {'subject': 'CAIs PCA91082'}, {'subject': 'adsorbed water on PCA91082 bulk'}, {'subject': 'matrix PCA91082 heated at 150C'}, {'subject': 'matrix PCA91082 heated at 300C'}, {'subject': 'matrix GRO95577 heated at 150C'}, {'subject': 'chondrules GRO95577'}, {'subject': 'CAIs GRO95577'}, {'subject': 'adsorbed water on GRO95577 bulk'}, {'subject': 'matrix GRO95577 heated at 300C'}, {'subject': 'laboratory measurement'}, {'subject': 'transmission'}, {'subject': 'macroscopic'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'absorbance'}]",['16 spectra'],['ASCII']
+10.26302/sshade/experiment_fs_20201007_002,Fe K edge XAS fluorescence of FeSO4 in buffer for the study of the Iron binding site in the mature and C-terminal regions of wild-type and mutant human frataxin.,SSHADE/FAME (OSUG Data Center),2022.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2022-11-02T11:14:29.000Z,2022-11-02T11:14:30.000Z,inist.sshade,mgeg,"commercial,molecular solid solution,Frozen solution of FeSO4,laboratory measurement,fluorescence emission,None,hard X,hard X-rays","[{'subject': 'commercial'}, {'subject': 'molecular solid solution'}, {'subject': 'Frozen solution of FeSO4'}, {'subject': 'laboratory measurement'}, {'subject': 'fluorescence emission'}, {'subject': 'None'}, {'subject': 'hard X'}, {'subject': 'hard X-rays'}]",['1 spectrum'],['ASCII']
+10.5281/zenodo.10568799,"Voter Autrement 2022 - The Online Experiment (""Un Autre Vote'')",Zenodo,2024.0,en,Dataset,ODC Open Database License v1.0," In April 2022, we have run a voting experiment during the French presidential election. During this experiment, participants were asked to test several alternative voting methods to elect the French president, like scoring methods, instant-runoff voting, Borda with partial rankings, majority judgement and pairwise comparisons. The experiment was both carried out in situ in polling stations during the first round of the presidential election (using paper ballots), and online between April 8th (two days before the first round of the election) and May 7th (using a web application). A total of 2308 participants took part in the online experiment. This dataset contains the answers provided by the participants to the online experiment, with no other processsing than a basic transformation to a set of CSV files.
+
+The companion paper available on this repository describes the experimental protocol, the format of the files, and summarizes the precise conditions under which this dataset is available.",api,True,findable,0.0,0.0,0.0,0.0,0.0,2024-01-30T15:47:32.000Z,2024-01-30T15:47:32.000Z,cern.zenodo,cern,"Election,Social Choice,Voting,Experimental Voting,Comsoc","[{'subject': 'Election'}, {'subject': 'Social Choice'}, {'subject': 'Voting'}, {'subject': 'Experimental Voting'}, {'subject': 'Comsoc'}]",,
+10.6084/m9.figshare.23575390,Additional file 11 of Decoupling of arsenic and iron release from ferrihydrite suspension under reducing conditions: a biogeochemical model,figshare,2023.0,,Text,Creative Commons Attribution 4.0 International,Authors’ original file for figure 10,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-06-25T03:12:05.000Z,2023-06-25T03:12:06.000Z,figshare.ars,otjm,"59999 Environmental Sciences not elsewhere classified,FOS: Earth and related environmental sciences,39999 Chemical Sciences not elsewhere classified,FOS: Chemical sciences,Ecology,FOS: Biological sciences,69999 Biological Sciences not elsewhere classified,Cancer","[{'subject': '59999 Environmental Sciences not elsewhere classified', 'schemeUri': 'http://www.abs.gov.au/ausstats/abs@.nsf/0/6BB427AB9696C225CA2574180004463E', 'subjectScheme': 'FOR'}, {'subject': 'FOS: Earth and related environmental sciences', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': '39999 Chemical Sciences not elsewhere classified', 'schemeUri': 'http://www.abs.gov.au/ausstats/abs@.nsf/0/6BB427AB9696C225CA2574180004463E', 'subjectScheme': 'FOR'}, {'subject': 'FOS: Chemical sciences', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': 'Ecology'}, {'subject': 'FOS: Biological sciences', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': '69999 Biological Sciences not elsewhere classified', 'schemeUri': 'http://www.abs.gov.au/ausstats/abs@.nsf/0/6BB427AB9696C225CA2574180004463E', 'subjectScheme': 'FOR'}, {'subject': 'Cancer'}]",['36864 Bytes'],
+10.26302/sshade/experiment_gl_20150103_1,Mid-infrared diffuse reflectance experiment with chlorite (clinochlore) heated in-situ from 25 to 860°C,SSHADE/LSD (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2022-11-04T08:25:07.000Z,2022-11-04T08:25:08.000Z,inist.sshade,mgeg,"mineral,natural terrestrial,phyllosilicate,clinochlore,commercial,elemental solid,Synthetic diamond powder,laboratory measurement,diffuse reflection,macroscopic,MIR,Mid-Infrared,absorbance","[{'subject': 'mineral'}, {'subject': 'natural terrestrial'}, {'subject': 'phyllosilicate'}, {'subject': 'clinochlore'}, {'subject': 'commercial'}, {'subject': 'elemental solid'}, {'subject': 'Synthetic diamond powder'}, {'subject': 'laboratory measurement'}, {'subject': 'diffuse reflection'}, {'subject': 'macroscopic'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'absorbance'}]",['4 spectra'],['ASCII']
+10.26302/sshade/experiment_ak_20141113_1,Mid-infrared attenuated total reflectance experiment with Cs+ exchanged less 1 μm size fraction of montmorillonite (SCa-3) equilibrated with D2O vapor under variable relative humidity,SSHADE/LSD (OSUG Data Center),2019.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2022-11-04T08:14:43.000Z,2022-11-04T08:14:44.000Z,inist.sshade,mgeg,"natural terrestrial,phyllosilicate,Cs-exchanged montmorillonite SCa-3 size-fraction &lt;1 µm,liquid,D2O 99.9 Sigma-Aldrich,laboratory measurement,ATReflection,macroscopic,MIR,Mid-Infrared,corrected ATR absorbance","[{'subject': 'natural terrestrial'}, {'subject': 'phyllosilicate'}, {'subject': 'Cs-exchanged montmorillonite SCa-3 size-fraction &lt;1 µm'}, {'subject': 'liquid'}, {'subject': 'D2O 99.9 Sigma-Aldrich'}, {'subject': 'laboratory measurement'}, {'subject': 'ATReflection'}, {'subject': 'macroscopic'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'corrected ATR absorbance'}]",['3 spectra'],['ASCII']
+10.26302/sshade/experiment_gs_20170713_010,Ag K edge XAS fluorescence of frozen Ag-GSH solution (pH=4),SSHADE/FAME (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2019-12-05T14:29:35.000Z,2019-12-05T14:31:02.000Z,inist.sshade,mgeg,"laboratory,molecular solid solution,Frozen Ag-GSH solution (pH=4),laboratory measurement,fluorescence emission,None,hard X,hard X-rays","[{'subject': 'laboratory'}, {'subject': 'molecular solid solution'}, {'subject': 'Frozen Ag-GSH solution (pH=4)'}, {'subject': 'laboratory measurement'}, {'subject': 'fluorescence emission'}, {'subject': 'None'}, {'subject': 'hard X'}, {'subject': 'hard X-rays'}]",['1 spectrum'],['ASCII']
+10.6084/m9.figshare.24946445,Additional file 1 of Barriers and facilitators to the HPV vaccine: a multicenter qualitative study of French general practitioners,figshare,2024.0,,Text,Creative Commons Attribution 4.0 International,Supplementary Table 1: interview guide,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2024-01-05T04:41:35.000Z,2024-01-05T04:41:35.000Z,figshare.ars,otjm,"Biological Sciences not elsewhere classified,Cancer,Science Policy,Infectious Diseases,FOS: Health sciences","[{'subject': 'Biological Sciences not elsewhere classified'}, {'subject': 'Cancer'}, {'subject': 'Science Policy'}, {'subject': 'Infectious Diseases'}, {'subject': 'FOS: Health sciences', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}]",['20755 Bytes'],
+10.6084/m9.figshare.c.6590285,"Individual and environmental determinants associated with longer times to access pediatric rheumatology centers for patients with juvenile idiopathic arthritis, a JIR cohort study",figshare,2023.0,,Collection,Creative Commons Attribution 4.0 International,"Abstract Background Despite guidelines, poor access to appropriate care for juvenile idiopathic arthritis (JIA) patients remains a global issue. Prompt referral to a pediatric rheumatology (PR) center and effective care is known to be critical for changing the natural history of the disease and improving long-term prognosis. This project assesses socio-economic factors of delayed referral to a pediatric rheumatologist (PRst) for JIA patients in France and Switzerland within the Juvenile Inflammatory Rheumatism (JIR) Cohort. Methods All patients diagnosed with JIA, presenting at one center of the JIRcohort in France or Switzerland with additional data on referral pathway were included. Patient characteristics at first visit to the PR center, dates of visits to healthcare providers during referral, and parent characteristics were extracted from the JIRcohort database. Results Two hundred fifty children were included. The overall median time to first PR assessment was 2.4 months [1.3; 6.9] and ranged widely across the JIA subtypes, from 1.4 months [0.6; 3.8] for children with systemic juvenile idiopathic arthritis (sJIA) to 5.3 months [2.0; 19.1] for children with enthesitis-related arthritis (ERA). A diagnosis of ERA and an appointment with an orthopedist during the referral pathway were significantly associated with a longer time before the first PR visit (hazard ratio HR 0.50 [95% CI: 0.29; 0.84]) and HR 0.68 [95% CI: 0.49; 0.93], respectively) in multivariable analysis. Having a mother with a post-graduate educational attainment level was tendentially associated with a shorter time before the first PR visit, (HR 1.32 [95% CI: 0.99; 1.78]). Conclusions Time to first PRst visit was most often short compared to other studies and close to the British recommendations. However, this time remained too long for many patients. We observed no social inequities in access to a PRst, but we show the need to improve effective pathway and access to a PR center for JIA patients.",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-04-13T13:55:20.000Z,2023-04-13T13:55:20.000Z,figshare.ars,otjm,"Medicine,Biotechnology,Ecology,FOS: Biological sciences,Immunology,FOS: Clinical medicine,Cancer,Science Policy","[{'subject': 'Medicine'}, {'subject': 'Biotechnology'}, {'subject': 'Ecology'}, {'subject': 'FOS: Biological sciences', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': 'Immunology'}, {'subject': 'FOS: Clinical medicine', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': 'Cancer'}, {'subject': 'Science Policy'}]",,
+10.26302/sshade/experiment_cl_20180316_03,MIR reflectance spectrum of a EET92159 CR chondrite pellet,SSHADE/DAYSY (OSUG Data Center),2022.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","Average MIR reflectance spectrum of a pellet of EET92159 CR chondrite, obtained by hyperspectral imaging",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2022-06-01T21:26:23.000Z,2022-06-01T21:26:23.000Z,inist.sshade,mgeg,"extraterrestrial,carbonaceous chondrite,CR,complex organic-mineral mix,matrix EET92159,complex mineral mix,chondrules EET92159,CAIs EET92159,laboratory measurement,confocal reflection,micro-imaging,MIR,Mid-Infrared,normalized reflectance","[{'subject': 'extraterrestrial'}, {'subject': 'carbonaceous chondrite'}, {'subject': 'CR'}, {'subject': 'complex organic-mineral mix'}, {'subject': 'matrix EET92159'}, {'subject': 'complex mineral mix'}, {'subject': 'chondrules EET92159'}, {'subject': 'CAIs EET92159'}, {'subject': 'laboratory measurement'}, {'subject': 'confocal reflection'}, {'subject': 'micro-imaging'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'normalized reflectance'}]",['1 spectrum'],['ASCII']
+10.26302/sshade/experiment_dm_20131017_001,"NIR reflectance spectra of mixtures of AMES tholins with liquid and solid CH4, C2H6 and CH3CN at several temperatures",SSHADE/SOSYPOL (OSUG Data Center),2020.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","NIR reflectance spectra of AMES tholins (from 90% N2:10% CH4) pure and mixed with different liquids and solids (CH4, C2H6 and CH3CN+C2N6) at temperatures from ambient to 88 K. Spectra were recorded upon cooling while the liquid was progressively added. Freezing occured at some point.",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2020-02-13T12:08:20.000Z,2020-02-13T12:08:21.000Z,inist.sshade,mgeg,"carbonaceous,laboratory,complex macromolecular mixture,Tholins AMES 90%N2:10%CH4,commercial,liquid,pure liquid CH4,Liquid C2H6,Liquid CH3CN,laboratory measurement,bidirectional reflection,macroscopic,NIR,Near-Infrared,reflectance factor","[{'subject': 'carbonaceous'}, {'subject': 'laboratory'}, {'subject': 'complex macromolecular mixture'}, {'subject': 'Tholins AMES 90%N2:10%CH4'}, {'subject': 'commercial'}, {'subject': 'liquid'}, {'subject': 'pure liquid CH4'}, {'subject': 'Liquid C2H6'}, {'subject': 'Liquid CH3CN'}, {'subject': 'laboratory measurement'}, {'subject': 'bidirectional reflection'}, {'subject': 'macroscopic'}, {'subject': 'NIR'}, {'subject': 'Near-Infrared'}, {'subject': 'reflectance factor'}]",['24 spectra'],['ASCII']
+10.5281/zenodo.10004947,Model Counting Competition 2020: Full Instance Set,Zenodo,2023.0,en,Dataset,Creative Commons Attribution 4.0 International,"The dataset contains all instances that the organizers of the competition received or collected during the preparation phase of the Model Counting Competition 2020. The dataset includes short benchmark descriptions (00_description.{pdf,txt,md}) by the submitters/collectors (00_authors.txt).
+For a more details, we refer to the reportFichte, Hecher, Hamiti: The Model Counting Competition 2020.
+-----Changelog:
+2023-10-17 (v2): We updated the instances to the most recent competition format in preparation for the report on the competitions 2021-2023. Note that the old instance set contained various instances with incorrect headers (less variables or clauses than in the actual data), unterminated lines, or a few broken lines. We corrected these instances by scripts that are available on github (daajoe:mc_format_tools).",api,True,findable,0.0,0.0,0.0,0.0,0.0,2024-02-15T17:44:01.000Z,2024-02-15T17:44:02.000Z,cern.zenodo,cern,,,,
+10.26302/sshade/experiment_bs_20130124_002,NIR Optical constants spectrum of SO2 crystal at 125 K,SSHADE/GhoSST (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",NIR Optical constants spectrum of SO2 crystal at 125 K,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2020-02-01T13:37:56.000Z,2020-02-01T13:37:56.000Z,inist.sshade,mgeg,"laboratory,inorganic molecular solid,SO2 crystalline I,laboratory measurement,transmission,macroscopic,NIR,Near-Infrared,optical constants","[{'subject': 'laboratory'}, {'subject': 'inorganic molecular solid'}, {'subject': 'SO2 crystalline I'}, {'subject': 'laboratory measurement'}, {'subject': 'transmission'}, {'subject': 'macroscopic'}, {'subject': 'NIR'}, {'subject': 'Near-Infrared'}, {'subject': 'optical constants'}]",['1 spectrum'],['ASCII']
+10.5281/zenodo.10551249,"Data supporting 'Ice loss in the European Alps until 2050 using a fully assimilated, deep-learning-aided 3D ice-flow model'",Zenodo,2024.0,en,Dataset,Creative Commons Attribution 4.0 International,"The dataset supporting our publication 'Ice loss in the European Alps until 2050 using a fully assimilated, deep-learning-aided 3D ice-flow model' in Geophysical Research Letters.
+
+The main .zip archive contains a set of NetCDF files detailing:
+
+
+
+Initial optimised glacier states (geology-optimized...)
+
+Simulation results (Prog20...)
+
+
+Initial states and results are given by cluster (see Figure 1 in the paper), as shown in all filenames (C1 through to C12). Prognostic simulation filenames additionally distinguish between runs between 1999 and 2019 (Prog2020) and between 2020 and 2050 (Prog2050). 'NV'/'NoVel' and 'NT'/'NoThk' refer to simulations using the partial optimisation (optimisation without including velocity/thickness observations) as detailed in the paper. 'AV' at the end of the filename denotes the integrated area/volume results file, as opposed to the 2D raster results file. A 'V' before the cluster designation shows that the simulation used the variable SMB as opposed to the fixed SMB (see the paper for details). 'ID' before the cluster designation shows that the simulation was using extrapolated SMB based on the trend in SMB since 2000, instead of assuming the continuation of the current SMB. 'ID' on its own denotes linear extrapolation and 'IDQ' denotes quadratic extrapolation (not used in the published paper). 'SMBF' in the filename shows that the simulation used the SMB-elevation feedback.
+
+The additional .zip archive contains the code of IGM v1.0 used to produce the model results. For details on installing and using IGM, please see the Github page at https://github.com/jouvetg/igm.
+
+A further .zip archive (in version 3 - Sims2010-2022.zip) contains the simulations based on linear extrapolation of the observed trend in SMB between 2010 and 2022, following the same nomenclature as in the principal archive (see above).",api,True,findable,0.0,0.0,0.0,0.0,0.0,2024-01-22T14:00:42.000Z,2024-01-22T14:00:42.000Z,cern.zenodo,cern,"Glacier,Alps,Numerical modelling,Deep learning,Climate change","[{'subject': 'Glacier'}, {'subject': 'Alps'}, {'subject': 'Numerical modelling'}, {'subject': 'Deep learning'}, {'subject': 'Climate change'}]",,
+10.26302/sshade/experiment_ak_20141118_1,Mid-infrared attenuated total reflectance experiment with Mg+ exchanged less 1 μm size fraction of nontronite (SWa-1) equilibrated with D2O vapor under variable relative humidity,SSHADE/LSD (OSUG Data Center),2019.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2022-11-04T08:21:26.000Z,2022-11-04T08:21:27.000Z,inist.sshade,mgeg,"natural terrestrial,phyllosilicate,Mg-exchanged smectite SWa-1 size-fraction &lt;1 µm,liquid,D2O 99.9 Sigma-Aldrich,laboratory measurement,ATReflection,macroscopic,MIR,Mid-Infrared,corrected ATR absorbance","[{'subject': 'natural terrestrial'}, {'subject': 'phyllosilicate'}, {'subject': 'Mg-exchanged smectite SWa-1 size-fraction &lt;1 µm'}, {'subject': 'liquid'}, {'subject': 'D2O 99.9 Sigma-Aldrich'}, {'subject': 'laboratory measurement'}, {'subject': 'ATReflection'}, {'subject': 'macroscopic'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'corrected ATR absorbance'}]",['5 spectra'],['ASCII']
+10.6084/m9.figshare.23983487,Additional file 2 of Aberrant activation of five embryonic stem cell-specific genes robustly predicts a high risk of relapse in breast cancers,figshare,2023.0,,Dataset,Creative Commons Attribution 4.0 International,"Additional file 2: Table S1. List of genes with predominant expression in testis, placenta and/or embryonic stem cells. Table S2. Frequencies of ectopic activations of the tissue-specific genes. Table S3. Results of the validation step in the biomarker discovery pipeline. Table S4. Datasets of normal tissues and breast cancers with corresponding sample sizes. Table S5. List of normal tissues and the corresponding sample sizes.",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-08-18T03:20:43.000Z,2023-08-18T03:20:44.000Z,figshare.ars,otjm,"Medicine,Cell Biology,Genetics,FOS: Biological sciences,Molecular Biology,Biological Sciences not elsewhere classified,Information Systems not elsewhere classified,Mathematical Sciences not elsewhere classified,Developmental Biology,Cancer,Plant Biology","[{'subject': 'Medicine'}, {'subject': 'Cell Biology'}, {'subject': 'Genetics'}, {'subject': 'FOS: Biological sciences', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': 'Molecular Biology'}, {'subject': 'Biological Sciences not elsewhere classified'}, {'subject': 'Information Systems not elsewhere classified'}, {'subject': 'Mathematical Sciences not elsewhere classified'}, {'subject': 'Developmental Biology'}, {'subject': 'Cancer'}, {'subject': 'Plant Biology'}]",['174460 Bytes'],
+10.26302/sshade/experiment_sb_20200609_001,Absorption coefficient in the VIS and NIR for a natural spinel,SSHADE/DOCCD (OSUG Data Center),2020.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2020-06-26T10:03:06.000Z,2020-06-26T10:03:07.000Z,inist.sshade,mgeg,"natural terrestrial,oxide-hydroxide,Spinel,laboratory measurement,transmission,macroscopic,Vis,Visible,NIR,Near-Infrared,MIR,Mid-Infrared,absorption coefficient","[{'subject': 'natural terrestrial'}, {'subject': 'oxide-hydroxide'}, {'subject': 'Spinel'}, {'subject': 'laboratory measurement'}, {'subject': 'transmission'}, {'subject': 'macroscopic'}, {'subject': 'Vis'}, {'subject': 'Visible'}, {'subject': 'NIR'}, {'subject': 'Near-Infrared'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'absorption coefficient'}]",['1 spectrum'],['ASCII']
+10.5281/zenodo.10471553,"Datasets used in ""Global LHC constraints on electroweak-inos with SModelS v2.3""",Zenodo,2024.0,en,Dataset,Creative Commons Attribution 4.0 International,"Input SLHA and SModelS output (.smodels and .py) files from the paper ""Global LHC constraints on electroweak-inos with SModelS v2.3"". The datasets comprises 18247 electroweak-ino scan points and can be used to reproduce results in sections 4 and 5, and in appendix B.
+
+
+
+ewino_slhaFiles.tar.gz : input SLHA files including mass spectra, decay tables and cross sections.
+
+ewino_smodels_mmg10.tar.gz : SModelS outputs with a minmassgap of 10 GeV (value used for the results presented in the main text, used for Figures 12-21). All the 18247 scan points present in the directory were obtained using this minmassgap.
+
+ewino_smodels_mmg05.tar.gz : SModelS outputs with a minmassgap of 5 GeV (value used in appendix B, used for Figures 23 and 24). All the 18247 scan points present in the directory were obtained using this minmassgap.
+
+ewino_smodels_mmg15.tar.gz : SModelS outputs with a minmassgap of 15 GeV (value used in appendix B, used for Figures 23 and 24). Only the points with a mass difference between the next-to-lightest neutralino and the lightest neutralino, or the next-to-lightest neutralino and the lightest chargino, or the lightest chargino and the lightest neutralino comprised between 10 and 15 GeV were computed using this minmassgap. This corresponds to 1732 scan points, which are listed in the summary.txt present in the compressed directory. The results for the remaining points were obtained using a minmassgap of 10 GeV.
+
+ewino_smodels_mmg20.tar.gz : SModelS outputs with a minmassgap of 20 GeV (value used in appendix B, used for Figures 23 and 24). Only the points with a mass difference between the next-to-lightest neutralino and the lightest neutralino, or the next-to-lightest neutralino and the lightest chargino, or the lightest chargino and the lightest neutralino comprised between 15 and 20 GeV were computed using this minmassgap. This corresponds to 870 scan points, which are listed in the summary.txt present in the compressed directory. The results for the remaining points were obtained using a minmassgap of 15 or 10 GeV (depending on the mass difference condition mentioned in the previous paragraph).
+
+combinability_matrix.py: python dictionnary modelling the combinability matrix (Figure 11).",api,True,findable,0.0,0.0,0.0,0.0,0.0,2024-01-09T20:45:54.000Z,2024-01-09T20:45:54.000Z,cern.zenodo,cern,"LHC,electroweak-ino,EW-ino,scan,likelihood,global constraint,SModelS,smodels,reinterpretation,simplified models,supersymmetry","[{'subject': 'LHC'}, {'subject': 'electroweak-ino'}, {'subject': 'EW-ino'}, {'subject': 'scan'}, {'subject': 'likelihood'}, {'subject': 'global constraint'}, {'subject': 'SModelS'}, {'subject': 'smodels'}, {'subject': 'reinterpretation'}, {'subject': 'simplified models'}, {'subject': 'supersymmetry'}]",,
+10.6084/m9.figshare.22620043,"Additional file 5 of Biallelic variants in NOS3 and GUCY1A3, the two major genes of the nitric oxide pathway, cause moyamoya cerebral angiopathy",figshare,2023.0,,Text,Creative Commons Attribution 4.0 International,Additional file 5: Quantitative PCR results comparing relative expression of NOS3 mRNA in cells transfected with the wild type and with the M035 mutated cDNA.,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-04-13T14:39:35.000Z,2023-04-13T14:44:39.000Z,figshare.ars,otjm,"Genetics,FOS: Biological sciences","[{'subject': 'Genetics'}, {'subject': 'FOS: Biological sciences', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}]",['14233 Bytes'],
+10.26302/sshade/experiment_jg_20090302_001,"Vis-NIR reflectance spectra of Kebri Dehar (Ogaden, Ethiopia) basalt cut",SSHADE/SOSYPOL (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","Vis-NIR reflectance spectra of the Kebri Dehar (Ogaden, Ethiopia) basalts altered in hot conditions with globally increasing aridity since Late Oligocene. The samples are cobble fragments sampled from the same outcrop. The experiment contains spectra of the fresh surface of the samples.",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2019-12-09T05:13:00.000Z,2019-12-09T05:13:01.000Z,inist.sshade,mgeg,"natural terrestrial,nesosilicate,olivine,inosilicate,pyroxenes,tektosilicate,plagioclases,phyllosilicate,smectites,silicate,iddingsite,laboratory measurement,bidirectional reflection,macroscopic,Vis,Visible,NIR,Near-Infrared,bidirectional reflectance","[{'subject': 'natural terrestrial'}, {'subject': 'nesosilicate'}, {'subject': 'olivine'}, {'subject': 'inosilicate'}, {'subject': 'pyroxenes'}, {'subject': 'tektosilicate'}, {'subject': 'plagioclases'}, {'subject': 'phyllosilicate'}, {'subject': 'smectites'}, {'subject': 'silicate'}, {'subject': 'iddingsite'}, {'subject': 'laboratory measurement'}, {'subject': 'bidirectional reflection'}, {'subject': 'macroscopic'}, {'subject': 'Vis'}, {'subject': 'Visible'}, {'subject': 'NIR'}, {'subject': 'Near-Infrared'}, {'subject': 'bidirectional reflectance'}]",['9 spectra'],['ASCII']
+10.6084/m9.figshare.24447574,Additional file 1 of Bacterial survival in radiopharmaceutical solutions: a critical impact on current practices,figshare,2023.0,,Dataset,Creative Commons Attribution 4.0 International,"Additional file 1. Raw data of Pseudomonas aeruginosa (ATCC: 27853), Staphylococcus aureus (ATCC: 25923) and Staphylococcus epidermidis (ATCC: 1228) survival rate in technetium-99m radioactive solutions at 1.85 to 11.1 GBq and non-radioactive technetium-99 solutions were reported.",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-10-27T03:41:27.000Z,2023-10-27T03:41:27.000Z,figshare.ars,otjm,"Biophysics,Microbiology,FOS: Biological sciences,Environmental Sciences not elsewhere classified,Science Policy,Infectious Diseases,FOS: Health sciences","[{'subject': 'Biophysics'}, {'subject': 'Microbiology'}, {'subject': 'FOS: Biological sciences', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': 'Environmental Sciences not elsewhere classified'}, {'subject': 'Science Policy'}, {'subject': 'Infectious Diseases'}, {'subject': 'FOS: Health sciences', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}]",['353871 Bytes'],
+10.26302/sshade/experiment_bs_20201114_010,"Near-infrared reflectance spectra at low temperature (300-80K) of Struvite [(NH4)MgPO4·6(H2O)] powders with three grain size ranges (32-80, 80-125 and 125-150µm)",SSHADE/CSS (OSUG Data Center),2022.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",Near-infrared reflectance spectra at low temperature (290-70K) of Struvite powder [(NH4)MgPO4·6(H2O)] with 32-80 µm grain size and at room temperature (300K) with 80-125µm and 125-150µm grain sizes,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2022-04-23T08:18:26.000Z,2022-04-23T08:18:27.000Z,inist.sshade,mgeg,"natural terrestrial,phosphate,Struvite,laboratory measurement,bidirectional reflection,macroscopic,NIR,Near-Infrared,reflectance factor","[{'subject': 'natural terrestrial'}, {'subject': 'phosphate'}, {'subject': 'Struvite'}, {'subject': 'laboratory measurement'}, {'subject': 'bidirectional reflection'}, {'subject': 'macroscopic'}, {'subject': 'NIR'}, {'subject': 'Near-Infrared'}, {'subject': 'reflectance factor'}]",['23 spectra'],['ASCII']
+10.26302/sshade/experiment_ak_20141117_1,Mid-infrared attenuated total reflectance experiment with Mg2+ exchanged less 1 μm size fraction of montmorillonite (SCa-3) equilibrated with D2O vapor under variable relative humidity,SSHADE/LSD (OSUG Data Center),2019.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2022-11-04T08:15:47.000Z,2022-11-04T08:15:47.000Z,inist.sshade,mgeg,"natural terrestrial,phyllosilicate,Mg-exchanged montmorillonite SCa-3 size-fraction &lt;1 µm,liquid,D2O 99.9 Sigma-Aldrich,laboratory measurement,ATReflection,macroscopic,MIR,Mid-Infrared,corrected ATR absorbance","[{'subject': 'natural terrestrial'}, {'subject': 'phyllosilicate'}, {'subject': 'Mg-exchanged montmorillonite SCa-3 size-fraction &lt;1 µm'}, {'subject': 'liquid'}, {'subject': 'D2O 99.9 Sigma-Aldrich'}, {'subject': 'laboratory measurement'}, {'subject': 'ATReflection'}, {'subject': 'macroscopic'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'corrected ATR absorbance'}]",['5 spectra'],['ASCII']
+10.5281/zenodo.10157946,X-ray diffraction images for HEN Egg White Lysozyme co-crystallized with 10mM TbXo4-OH - PDB ID: 8P2Q,Zenodo,2023.0,,Dataset,Creative Commons Attribution 4.0 International,"Xray diffraction images for HEWL co-crystallized with 10mM TbXo4-OH. Dataset collected at SOLEIL - Proxima 1 (PX1) beamline. For experimental details, see XDS.INP file (input file for XDS program).",api,True,findable,0.0,0.0,0.0,0.0,0.0,2024-01-18T23:50:03.000Z,2024-01-18T23:50:03.000Z,cern.zenodo,cern,,,,
+10.26302/sshade/experiment_rc_20191104_000,VIS-NIR reflectance spectra collected during low-temperature and near-vacuum sublimation of compact slabs of salty ice produced by slowly freezing solutions of NaCl with three different concentrations,SSHADE/BYPASS (OSUG Data Center),2023.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",Compact slabs of salty ice are produced by slowly freezing small volumes of salt solutions into a laboratory freezer at 230K. The samples are then introduced in the SCITEAS-2 simulations chamber and their slow sublimation at low temperature and in secondary vacuum is followed for several tens of hours by VIS-NIR hyperspectral imaging.,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-06-09T17:17:15.000Z,2023-06-09T17:17:16.000Z,inist.sshade,mgeg,"laboratory measurement,biconical reflection,imaging,Vis,Visible,NIR,Near-Infrared,reflectance factor,water ice,NaCl hydrate,laboratory,inorganic molecular solid,chloride","[{'subject': 'laboratory measurement', 'subjectScheme': 'main'}, {'subject': 'biconical reflection', 'subjectScheme': 'main'}, {'subject': 'imaging', 'subjectScheme': 'main'}, {'subject': 'Vis', 'subjectScheme': 'variables'}, {'subject': 'Visible', 'subjectScheme': 'variables'}, {'subject': 'NIR', 'subjectScheme': 'variables'}, {'subject': 'Near-Infrared', 'subjectScheme': 'variables'}, {'subject': 'reflectance factor', 'subjectScheme': 'variables'}, {'subject': 'water ice', 'subjectScheme': 'name'}, {'subject': 'NaCl hydrate', 'subjectScheme': 'name'}, {'subject': 'laboratory', 'subjectScheme': 'origin'}, {'subject': 'inorganic molecular solid', 'subjectScheme': 'compound type'}, {'subject': 'chloride', 'subjectScheme': 'compound type'}]",['180 spectra'],['ASCII']
+10.5281/zenodo.10676308,NeoGeographyToolkit/StereoPipeline: 2024-02-18-daily-build,Zenodo,2024.0,,Software,Creative Commons Attribution 4.0 International,Recent additions log: https://stereopipeline.readthedocs.io/en/latest/news.html,api,True,findable,0.0,0.0,0.0,0.0,0.0,2024-02-18T17:06:45.000Z,2024-02-18T17:06:46.000Z,cern.zenodo,cern,,,,
+10.26302/sshade/bandlist_raman_calcite,Raman bandlist of natural Calcite,SSHADE/BANDLIST (OSUG Data Center),2021.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",MIR-FIR Raman bandlist of natural Calcite at 295K and 80K,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-04-22T06:33:27.000Z,2023-04-22T06:33:28.000Z,inist.sshade,mgeg,"Calcite,Calcium cation,Carbonate anion,Calcium(2+) cation,14127-61-8,471-34-1,Ca2+,(CO3)2-,CaCO3,Calcite,non-silicate mineral,carbonate,carbonates, nitrates, borates,anhydrous carbonates,Calcite group (Trigonal: R-3c),14.01.01.01,05.AB.05,Raman scattering,MIR,FIR,band frequency,band width,band intensity,transition and vibration modes","[{'subject': 'Calcite', 'subjectScheme': 'name'}, {'subject': 'Calcium cation', 'subjectScheme': 'name'}, {'subject': 'Carbonate anion', 'subjectScheme': 'name'}, {'subject': 'Calcium(2+) cation', 'subjectScheme': 'IUPAC name'}, {'subject': '14127-61-8', 'subjectScheme': 'CAS number'}, {'subject': '471-34-1', 'subjectScheme': 'CAS number'}, {'subject': 'Ca2+', 'subjectScheme': 'formula'}, {'subject': '(CO3)2-', 'subjectScheme': 'formula'}, {'subject': 'CaCO3', 'subjectScheme': 'formula'}, {'subject': 'Calcite', 'subjectScheme': 'IMA name'}, {'subject': 'non-silicate mineral', 'subjectScheme': 'mineral class'}, {'subject': 'carbonate', 'subjectScheme': 'compound type'}, {'subject': 'carbonates, nitrates, borates', 'subjectScheme': 'Dana class'}, {'subject': 'anhydrous carbonates', 'subjectScheme': 'Dana class'}, {'subject': 'Calcite group (Trigonal: R-3c)', 'subjectScheme': 'Dana group'}, {'subject': '14.01.01.01', 'subjectScheme': 'Dana code'}, {'subject': '05.AB.05', 'subjectScheme': 'Strunz code'}, {'subject': 'Raman scattering', 'subjectScheme': 'variables'}, {'subject': 'MIR', 'subjectScheme': 'variables'}, {'subject': 'FIR', 'subjectScheme': 'variables'}, {'subject': 'band frequency', 'subjectScheme': 'variables'}, {'subject': 'band width', 'subjectScheme': 'variables'}, {'subject': 'band intensity', 'subjectScheme': 'variables'}, {'subject': 'transition and vibration modes', 'subjectScheme': 'variables'}]",,['ASCII']
+10.26302/sshade/experiment_vc_20050726_001,Vis-NIR reflectance spectra of Australia white sand wetted with water and dried in ambiant air at 38°C,SSHADE/SSTONE (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","In order to investigate the spectral behavior of humidity on sand spectra, we have acquired laboratory reflectance spectra of a sand containing various proportion of water. Water was deposited on a dry sand (previously dried in an oven at 40°C during one night). During the experiment, the sample is then dried, under the sun at 38°C. A spectrum is acquired every 5 minutes with an ASD FieldSpec3FR. This experiment was done on Australia white sand",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-04-22T08:30:42.000Z,2023-04-22T08:30:42.000Z,inist.sshade,mgeg,"laboratory measurement,bidirectional reflection,macroscopic,Vis,Visible,NIR,Near-Infrared,bidirectional reflectance,Quartz,Orthoclase,Albite,Liquid water,mineral,natural terrestrial,tektosilicate,liquid","[{'subject': 'laboratory measurement', 'subjectScheme': 'main'}, {'subject': 'bidirectional reflection', 'subjectScheme': 'main'}, {'subject': 'macroscopic', 'subjectScheme': 'main'}, {'subject': 'Vis', 'subjectScheme': 'var'}, {'subject': 'Visible', 'subjectScheme': 'var'}, {'subject': 'NIR', 'subjectScheme': 'var'}, {'subject': 'Near-Infrared', 'subjectScheme': 'var'}, {'subject': 'bidirectional reflectance', 'subjectScheme': 'var'}, {'subject': 'Quartz', 'subjectScheme': 'name'}, {'subject': 'Orthoclase', 'subjectScheme': 'name'}, {'subject': 'Albite', 'subjectScheme': 'name'}, {'subject': 'Liquid water', 'subjectScheme': 'name'}, {'subject': 'mineral', 'subjectScheme': 'family'}, {'subject': 'natural terrestrial', 'subjectScheme': 'origin'}, {'subject': 'tektosilicate', 'subjectScheme': 'compound type'}, {'subject': 'liquid', 'subjectScheme': 'compound type'}]",['27 spectra'],['ASCII']
+10.26302/sshade/bandlist_raman_gaspeite,Raman bandlist of natural Gaspeite,SSHADE/BANDLIST (OSUG Data Center),2023.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",MIR-FIR Raman bandlist of natural Gaspeite at 295K,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-08-14T21:37:40.000Z,2023-08-14T21:37:41.000Z,inist.sshade,mgeg,"Gaspeite,Nickel cation,Carbonate anion,Nickel(2+) cation,14701-22-5,Ni2+,(CO3)2-,NiCO3,Gaspeite,non-silicate mineral,carbonate,carbonates, nitrates, borates,anhydrous carbonates,Calcite group (Trigonal: R-3c),14.01.01.08,05.AB.05,Raman scattering,FIR,MIR,band frequency,band width,band intensity,transition and vibration modes","[{'subject': 'Gaspeite', 'subjectScheme': 'name'}, {'subject': 'Nickel cation', 'subjectScheme': 'name'}, {'subject': 'Carbonate anion', 'subjectScheme': 'name'}, {'subject': 'Nickel(2+) cation', 'subjectScheme': 'IUPAC name'}, {'subject': '14701-22-5', 'subjectScheme': 'CAS number'}, {'subject': 'Ni2+', 'subjectScheme': 'formula'}, {'subject': '(CO3)2-', 'subjectScheme': 'formula'}, {'subject': 'NiCO3', 'subjectScheme': 'formula'}, {'subject': 'Gaspeite', 'subjectScheme': 'IMA name'}, {'subject': 'non-silicate mineral', 'subjectScheme': 'mineral class'}, {'subject': 'carbonate', 'subjectScheme': 'compound type'}, {'subject': 'carbonates, nitrates, borates', 'subjectScheme': 'Dana class'}, {'subject': 'anhydrous carbonates', 'subjectScheme': 'Dana class'}, {'subject': 'Calcite group (Trigonal: R-3c)', 'subjectScheme': 'Dana group'}, {'subject': '14.01.01.08', 'subjectScheme': 'Dana code'}, {'subject': '05.AB.05', 'subjectScheme': 'Strunz code'}, {'subject': 'Raman scattering', 'subjectScheme': 'variables'}, {'subject': 'FIR', 'subjectScheme': 'variables'}, {'subject': 'MIR', 'subjectScheme': 'variables'}, {'subject': 'band frequency', 'subjectScheme': 'variables'}, {'subject': 'band width', 'subjectScheme': 'variables'}, {'subject': 'band intensity', 'subjectScheme': 'variables'}, {'subject': 'transition and vibration modes', 'subjectScheme': 'variables'}]",,['ASCII']
+10.15778/resif.xt2018,Seismic network XT: CIFALPS-2 temporary experiment (China-Italy-France Alps seismic transect #2,RESIF - Réseau Sismologique et géodésique Français,2018.0,en,Dataset,"Open Access,Creative Commons Attribution 4.0 International","Temporary seismic array of broadband stations deployed along a transect across the northwestern Alps (France and Italy). Duration: 14-15 months. 43 stations in a 400-km long linear array, from eastern Massif Central (France) to the Ligurian coast (Italy) across the Mont Blanc and Gran Paradiso massifs; 7 km average spacing. Two additional short lines of 6 stations each 20 km to the NE and SW of the main line in the region between the cities of Aosta and Ivrea (Italy). Goal: imaging of the crust and upper mantle using earthquakes and noise records. Sensors: mostly Nanometrics Trillium Horizon, with a few Guralp CMG40T (30 or 60s). Digitizers: Nanometrics Centaur and a few Taurus.",mds,True,findable,0.0,0.0,0.0,3.0,0.0,2019-09-13T06:13:18.000Z,2019-09-13T06:13:18.000Z,inist.resif,vcob,"seismic tomography,lithosphere,Alpine belt,broadband seismology,crust,upper mantle,seismicity","[{'subject': 'seismic tomography'}, {'subject': 'lithosphere'}, {'subject': 'Alpine belt'}, {'subject': 'broadband seismology'}, {'subject': 'crust'}, {'subject': 'upper mantle'}, {'subject': 'seismicity'}]","['55 stations, 711 Gb']","['Miniseed data data', 'stationXML metadata']"
+10.26302/sshade/experiment_ak_20141124_1,Mid-infrared attenuated total reflectance experiment with Ca+ exchanged less 0.1 μm size fraction of montmorillonite (SWy-2) equilibrated with H2O vapor under variable relative humidity,SSHADE/LSD (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2022-11-04T08:20:07.000Z,2022-11-04T08:20:08.000Z,inist.sshade,mgeg,"natural terrestrial,phyllosilicate,Ca-exchanged montmorillonite SWy-2 size-fraction &lt;0.1 µm,liquid,H2O deionized,laboratory measurement,ATReflection,macroscopic,MIR,Mid-Infrared,corrected ATR absorbance","[{'subject': 'natural terrestrial'}, {'subject': 'phyllosilicate'}, {'subject': 'Ca-exchanged montmorillonite SWy-2 size-fraction &lt;0.1 µm'}, {'subject': 'liquid'}, {'subject': 'H2O deionized'}, {'subject': 'laboratory measurement'}, {'subject': 'ATReflection'}, {'subject': 'macroscopic'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'corrected ATR absorbance'}]",['9 spectra'],['ASCII']
+10.26302/sshade/experiment_lb_20170718_001,"Mid-IR absorbance spectra of 5 bulk CV chondrites in KBr pellets at ambient temperature, 150°C and 300°C",SSHADE/GhoSST (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","Mid-IR absorbance spectra of 5 bulk CV chondrites (Allende, Mokoia, Grosnaja, Kaba, Vigarano) in KBr pellets at 3 different temperatures: ambient temperature, 150°C and 300°C",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2021-01-15T07:09:35.000Z,2021-01-15T07:09:36.000Z,inist.sshade,mgeg,"extraterrestrial,complex organic-mineral mix,matrix Allende,complex mineral mix,chondrules Allende,CAIs Allende,physically adsorbed phase,adsorbed water on Allende bulk,commercial,bromide,KBr,adsorbed water on KBr (Beck14),matrix Allende heated at 150C,matrix Allende heated at 300C,matrix Grosnaja,chondrules Grosnaja,CAIs Grosnaja,adsorbed water on Grosnaja bulk,matrix Grosnaja heated at 150C,matrix Grosnaja heated at 300C,chondrules Kaba,CAIs Kaba,adsorbed water on Kaba bulk,matrix Kaba heated at 150C,matrix Kaba heated at 300C,matrix Mokoia,chondrules Mokoia,CAIs Mokoia,adsorbed water on Mokoia bulk,matrix Mokoia heated at 150C,matrix Mokoia heated at 300C,matrix Vigarano,chondrules Vigarano,CAIs Vigarano,adsorbed water on Vigarano bulk,matrix Vigarano heated at 150C,matrix Vigarano heated at 300C,laboratory measurement,transmission,macroscopic,MIR,Mid-Infrared,absorbance","[{'subject': 'extraterrestrial'}, {'subject': 'complex organic-mineral mix'}, {'subject': 'matrix Allende'}, {'subject': 'complex mineral mix'}, {'subject': 'chondrules Allende'}, {'subject': 'CAIs Allende'}, {'subject': 'physically adsorbed phase'}, {'subject': 'adsorbed water on Allende bulk'}, {'subject': 'commercial'}, {'subject': 'bromide'}, {'subject': 'KBr'}, {'subject': 'adsorbed water on KBr (Beck14)'}, {'subject': 'matrix Allende heated at 150C'}, {'subject': 'matrix Allende heated at 300C'}, {'subject': 'matrix Grosnaja'}, {'subject': 'chondrules Grosnaja'}, {'subject': 'CAIs Grosnaja'}, {'subject': 'adsorbed water on Grosnaja bulk'}, {'subject': 'matrix Grosnaja heated at 150C'}, {'subject': 'matrix Grosnaja heated at 300C'}, {'subject': 'chondrules Kaba'}, {'subject': 'CAIs Kaba'}, {'subject': 'adsorbed water on Kaba bulk'}, {'subject': 'matrix Kaba heated at 150C'}, {'subject': 'matrix Kaba heated at 300C'}, {'subject': 'matrix Mokoia'}, {'subject': 'chondrules Mokoia'}, {'subject': 'CAIs Mokoia'}, {'subject': 'adsorbed water on Mokoia bulk'}, {'subject': 'matrix Mokoia heated at 150C'}, {'subject': 'matrix Mokoia heated at 300C'}, {'subject': 'matrix Vigarano'}, {'subject': 'chondrules Vigarano'}, {'subject': 'CAIs Vigarano'}, {'subject': 'adsorbed water on Vigarano bulk'}, {'subject': 'matrix Vigarano heated at 150C'}, {'subject': 'matrix Vigarano heated at 300C'}, {'subject': 'laboratory measurement'}, {'subject': 'transmission'}, {'subject': 'macroscopic'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'absorbance'}]",['15 spectra'],['ASCII']
+10.15778/resif.ya2009,"UNDERVOLC experiment, 2009-2011, code YA (Understanding volcanic processes)",RESIF - Réseau Sismologique et géodésique Français,2014.0,en,Other,"Open Access,Creative Commons Attribution 4.0 International","UnderVolc is a broadband seismic experiment that recorded 5 eruptions of Piton de la Fournaise Volcano, La Réunion island from 2009 to 2011.",mds,True,findable,0.0,0.0,0.0,1.0,0.0,2016-05-18T15:51:26.000Z,2016-05-18T15:51:26.000Z,inist.resif,vcob,"Réunion Hotspot,Piton de la Fournaise volcano","[{'subject': 'Réunion Hotspot'}, {'subject': 'Piton de la Fournaise volcano'}]",,
+10.26302/sshade/experiment_ak_20141115_1,Mid-infrared attenuated total reflectance experiment with Cs+ exchanged less 2 μm size fraction of montmorillonite (SAz-2) equilibrated with D2O vapor under variable relative humidity,SSHADE/LSD (OSUG Data Center),2019.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2022-11-04T08:15:03.000Z,2022-11-04T08:15:04.000Z,inist.sshade,mgeg,"natural terrestrial,phyllosilicate,Cs-exchanged montmorillonite SAz-2 size-fraction &lt;2 µm,liquid,D2O 99.9 Sigma-Aldrich,laboratory measurement,ATReflection,macroscopic,MIR,Mid-Infrared,corrected ATR absorbance","[{'subject': 'natural terrestrial'}, {'subject': 'phyllosilicate'}, {'subject': 'Cs-exchanged montmorillonite SAz-2 size-fraction &lt;2 µm'}, {'subject': 'liquid'}, {'subject': 'D2O 99.9 Sigma-Aldrich'}, {'subject': 'laboratory measurement'}, {'subject': 'ATReflection'}, {'subject': 'macroscopic'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'corrected ATR absorbance'}]",['3 spectra'],['ASCII']
+10.26302/sshade/experiment_dt_20180117_009,Zr K edge XAS transmission of Zr metallic foil reference at ambient conditions,SSHADE/FAME (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2019-11-15T20:31:46.000Z,2019-11-15T20:31:47.000Z,inist.sshade,mgeg,"commercial,elemental solid,metallic Zr,laboratory measurement,transmission,None,hard X,hard X-rays","[{'subject': 'commercial'}, {'subject': 'elemental solid'}, {'subject': 'metallic Zr'}, {'subject': 'laboratory measurement'}, {'subject': 'transmission'}, {'subject': 'None'}, {'subject': 'hard X'}, {'subject': 'hard X-rays'}]",['1 spectrum'],['ASCII']
+10.5281/zenodo.10440363,Replication package for article: From low-level fault modeling (of a pipeline attack) to a proven hardening scheme,Zenodo,2024.0,en,Software,,"This software package is the Docker image of a project about protecting RISC-V processors against certain low-level fault attacks. It mainly contains a modified LLVM, GNU binutils, QEMU, and test scripts.
+
+Project repository from which this image is built: https://gricad-gitlab.univ-grenoble-alpes.fr/michelse/fetch-skips-hardening
+
+Instructions for using this software and reproducing results: https://gricad-gitlab.univ-grenoble-alpes.fr/michelse/fetch-skips-hardening/-/blob/main/README.md?ref_type=heads
+
+ ",api,True,findable,0.0,0.0,0.0,0.0,0.0,2024-01-04T00:26:28.000Z,2024-01-04T00:26:28.000Z,cern.zenodo,cern,"Compilation,Fault models,Hardware security","[{'subject': 'Compilation'}, {'subject': 'Fault models'}, {'subject': 'Hardware security'}]",,
+10.15778/resif.zo2018,Dense nodal seismic array temporary experiment on Alpine Glacier of Argentière (RESIF-SISMOB),RESIF - Réseau Sismologique et géodésique Français,2020.0,,Dataset,"Open Access,Creative Commons Attribution 4.0 International","Seismology can yield key observational insights on glacier dynamical processes and structure characteristics. Spatializing the information gained from seismic signals however requires the deployment of dense seismic arrays, which has recently become routine in a wide range of geophysical contexts but has remained limited in glaciated environments. Here we present a dense seismic array experiment made of 98, 3-component and 35-days-long continuous records acquired in early spring on the Argentière Glacier, French Alps. The seismic dataset is supplemented by a wide range of complementary observations obtained from ground penetrating radar, drone imagery, GPS positioning and in-situ instrumentation of basal glacier sliding velocities and water flow discharge. Our objective is to provide a comprehensive dataset that enables (i) investigating with unprecedented spatial definition a wide range of glacier seismic sources and structural characteristics associated with e.g. englacial fracturing, ice-bed sliding or englacial and subglacial water flow, as well as (ii) linking these seismically-derived findings to spatial and temporal changes in the overall glacier dynamics and structure. We argue that the present dataset gathers all the necessary components to reach these objectives. We report that important dynamical and structural changes occur during the seismically monitored time period and spatial area. We also conduct a wide range of classical seismic processing techniques including amplitude analysis, event picking from pattern matching and systematic beamforming that suggest a wide range of glacier sources and structural changes are detectable with our dense seismic array and their spatial and temporal dynamics may be studied in details in future studies.",fabrica,True,findable,0.0,0.0,0.0,2.0,0.0,2020-07-02T10:31:19.000Z,2020-07-02T10:31:52.000Z,inist.resif,vcob,"Argentiere glacier,dense seismic array,multiphysics approach","[{'subject': 'Argentiere glacier'}, {'subject': 'dense seismic array'}, {'subject': 'multiphysics approach'}]","['102 stations, 1.7Tb (miniseed format)']","['Miniseed data', 'hdf5 data', 'stationXML metadata']"
+10.26302/sshade/experiment_op_20180115_004,Br K edge XAS transmission and HERFD of rubidium bromide anydrous salt at ambient conditions,SSHADE/FAME (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2020-10-29T16:52:13.000Z,2020-11-02T16:13:57.000Z,inist.sshade,mgeg,"solid,commercial,non-oxide ceramic,BN powder,laboratory,bromide,Rubidium bromide anydrous salt,laboratory measurement,transmission,None,hard X,hard X-rays,fluorescence emission","[{'subject': 'solid'}, {'subject': 'commercial'}, {'subject': 'non-oxide ceramic'}, {'subject': 'BN powder'}, {'subject': 'laboratory'}, {'subject': 'bromide'}, {'subject': 'Rubidium bromide anydrous salt'}, {'subject': 'laboratory measurement'}, {'subject': 'transmission'}, {'subject': 'None'}, {'subject': 'hard X'}, {'subject': 'hard X-rays'}, {'subject': 'fluorescence emission'}]",['2 spectra'],['ASCII']
+10.26302/sshade/experiment_ak_20141119_1,Mid-infrared attenuated total reflectance experiment with Ca2+ exchanged less 1 μm size fraction of beidellite (SbCa-1) equilibrated with D2O vapor under variable relative humidity,SSHADE/LSD (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2022-11-04T08:15:26.000Z,2022-11-04T08:15:26.000Z,inist.sshade,mgeg,"natural terrestrial,phyllosilicate,Ca-exchanged beidellite SbCa-1 size-fraction &lt;1 µm,liquid,D2O 99.9 Sigma-Aldrich,laboratory measurement,ATReflection,macroscopic,MIR,Mid-Infrared,corrected ATR absorbance","[{'subject': 'natural terrestrial'}, {'subject': 'phyllosilicate'}, {'subject': 'Ca-exchanged beidellite SbCa-1 size-fraction &lt;1 µm'}, {'subject': 'liquid'}, {'subject': 'D2O 99.9 Sigma-Aldrich'}, {'subject': 'laboratory measurement'}, {'subject': 'ATReflection'}, {'subject': 'macroscopic'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'corrected ATR absorbance'}]",['4 spectra'],['ASCII']
+10.26302/sshade/experiment_dt_20170704_001,Fe K edge XAS transmission of natural magnetite Fe3O4 at ambient conditions,SSHADE/FAME (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2019-11-15T20:28:06.000Z,2019-11-15T20:28:06.000Z,inist.sshade,mgeg,"solid,commercial,non-oxide ceramic,BN powder,natural terrestrial,oxide-hydroxide,Natural magnetite Fe3O4,laboratory measurement,transmission,None,hard X,hard X-rays","[{'subject': 'solid'}, {'subject': 'commercial'}, {'subject': 'non-oxide ceramic'}, {'subject': 'BN powder'}, {'subject': 'natural terrestrial'}, {'subject': 'oxide-hydroxide'}, {'subject': 'Natural magnetite Fe3O4'}, {'subject': 'laboratory measurement'}, {'subject': 'transmission'}, {'subject': 'None'}, {'subject': 'hard X'}, {'subject': 'hard X-rays'}]",['1 spectrum'],['ASCII']
+10.5281/zenodo.10444954,Data and code associated with the manuscript: Three centuries of snowpack decline at an Alpine pass revealed by cosmogenic paleothermometry and luminescence photochronometry,Zenodo,2023.0,,Dataset,GNU General Public License v3.0 or later,"This dataset contains the data as well as the Matlab codes needed to reproduce the results in the following manuscript:
+
+Guralnik, B., Tremblay, M.M., Phillips, M., Sellwood, E.L., Gribenski, N., Presl, R., Haberkorn, A., Sohbati, R., Shuster, D.L., Valla, P., Jain, M., Schindler, K., Wallinga, J., and Hippe, K., Three centuries of snowpack decline at an Alpine pass revealed by cosmogenic paleothermometry and luminescence photochronometry. 
+
+Briefly, this manuscript presents novel datasets of cosmogenic paleothermometery (quartz He-3) and luminescence photochronometery (feldspar IRSL), whose pairing constrains the temperature and insolation history of three bedrock outcrops at the Gotthard Pass in Switzerland over the last ~15,000 years. 
+
+The data include (1) measured concentrations of cosmogenic Be-10, C-14, and He-3 in quartz, (2) stepwise degassing experiments on proton irradiated quartz grains that are used to determine sample-specific He-3 diffusion kinetics, (3) best-fit multiple diffusion domain (MDD) models to the proton-induced He-3 diffusion experiments, (5) Natural radioactivity and calculated feldspar infrared stimulated luminescence (ISRL) dose rates, (6) feldspar ISRL depth profiles, and (7) high-resolution microrelief surface scans and analysis.
+
+The code includes scripts necessary to reproduce the figures and results associated with this manuscript. The code is organized by figure into subfolders, and any data needed to reproduce a figure should be included in that folder. All original codes are distributed under the GNU General Public License. Codes written by others and utilized here are redistributed under their original license according to the terms and conditions therein, and are provided in the folder 'external.'
+
+Any questions about original Matlab codes published here should be directed to Benny Guralnik, benny.guralnik@gmail.com.",api,True,findable,0.0,0.0,0.0,0.0,0.0,2023-12-30T17:14:33.000Z,2023-12-30T17:14:34.000Z,cern.zenodo,cern,"snow,cosmogenic,paleothermometry,luminescence,Alpine","[{'subject': 'snow'}, {'subject': 'cosmogenic'}, {'subject': 'paleothermometry'}, {'subject': 'luminescence'}, {'subject': 'Alpine'}]",,
+10.26302/sshade/experiment_lb_20191220_002,"NIR reflectance spectrum (i=0°, e=30°) of bulk CO chondrites under vacuum at T = 80°C",SSHADE/GhoSST (OSUG Data Center),2020.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","NIR reflectance spectra (i = 0°, e=30°) of bulk CO chondrites under vacuum at T = 80°C",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2020-08-13T09:14:49.000Z,2020-08-13T09:14:51.000Z,inist.sshade,mgeg,"extraterrestrial,carbonaceous chondrite,CO,complex organic-mineral mix,matrix ALHA77003,complex mineral mix,chondrules ALHA77003,CAIs ALHA77003,matrix DOM08006,chondrules DOM08006,CAIs DOM08006,matrix MIL05024,chondrules MIL05024,CAIs MIL05024,matrix MIL07193,chondrules MIL07193,CAIs MIL07193,matrix ALH83108,chondrules ALH83108,CAIs ALH83108,matrix EET92126,chondrules EET92126,CAIs EET92126,matrix MET00737,chondrules MET00737,CAIs MET00737,matrix MIL05104,chondrules MIL05104,CAIs MIL05104,matrix MIL07687,chondrules MIL07687,CAIs MIL07687,matrix MIL07709,chondrules MIL07709,CAIs MIL07709,matrix Moss,chondrules Moss,CAIs Moss,matrix Kainsaz,chondrules Kainsaz,CAIs Kainsaz,matrix LAP031117,chondrules LAP031117,CAIs LAP031117,matrix QUE97416,chondrules QUE97416,CAIs QUE97416,matrix ALH85003,chondrules ALH85003,CAIs ALH85003,matrix DOM03238,chondrules DOM03238,CAIs DOM03238,laboratory measurement,bidirectional reflection,macroscopic,Vis,Visible,NIR,Near-Infrared,reflectance factor","[{'subject': 'extraterrestrial'}, {'subject': 'carbonaceous chondrite'}, {'subject': 'CO'}, {'subject': 'complex organic-mineral mix'}, {'subject': 'matrix ALHA77003'}, {'subject': 'complex mineral mix'}, {'subject': 'chondrules ALHA77003'}, {'subject': 'CAIs ALHA77003'}, {'subject': 'matrix DOM08006'}, {'subject': 'chondrules DOM08006'}, {'subject': 'CAIs DOM08006'}, {'subject': 'matrix MIL05024'}, {'subject': 'chondrules MIL05024'}, {'subject': 'CAIs MIL05024'}, {'subject': 'matrix MIL07193'}, {'subject': 'chondrules MIL07193'}, {'subject': 'CAIs MIL07193'}, {'subject': 'matrix ALH83108'}, {'subject': 'chondrules ALH83108'}, {'subject': 'CAIs ALH83108'}, {'subject': 'matrix EET92126'}, {'subject': 'chondrules EET92126'}, {'subject': 'CAIs EET92126'}, {'subject': 'matrix MET00737'}, {'subject': 'chondrules MET00737'}, {'subject': 'CAIs MET00737'}, {'subject': 'matrix MIL05104'}, {'subject': 'chondrules MIL05104'}, {'subject': 'CAIs MIL05104'}, {'subject': 'matrix MIL07687'}, {'subject': 'chondrules MIL07687'}, {'subject': 'CAIs MIL07687'}, {'subject': 'matrix MIL07709'}, {'subject': 'chondrules MIL07709'}, {'subject': 'CAIs MIL07709'}, {'subject': 'matrix Moss'}, {'subject': 'chondrules Moss'}, {'subject': 'CAIs Moss'}, {'subject': 'matrix Kainsaz'}, {'subject': 'chondrules Kainsaz'}, {'subject': 'CAIs Kainsaz'}, {'subject': 'matrix LAP031117'}, {'subject': 'chondrules LAP031117'}, {'subject': 'CAIs LAP031117'}, {'subject': 'matrix QUE97416'}, {'subject': 'chondrules QUE97416'}, {'subject': 'CAIs QUE97416'}, {'subject': 'matrix ALH85003'}, {'subject': 'chondrules ALH85003'}, {'subject': 'CAIs ALH85003'}, {'subject': 'matrix DOM03238'}, {'subject': 'chondrules DOM03238'}, {'subject': 'CAIs DOM03238'}, {'subject': 'laboratory measurement'}, {'subject': 'bidirectional reflection'}, {'subject': 'macroscopic'}, {'subject': 'Vis'}, {'subject': 'Visible'}, {'subject': 'NIR'}, {'subject': 'Near-Infrared'}, {'subject': 'reflectance factor'}]",['16 spectra'],['ASCII']
+10.26302/sshade/experiment_zed_20220831_001,Vis-NIR BRDF spectra of serpentine pellets irradiated by Ar+ and He+.,SSHADE/DAYSY (OSUG Data Center),2022.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",Vis-NIR (0.4 - 4 µm) BRDF spectra of Rawhide serpentine pellet non-irradiated and irradiated by Ar+ and He+,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2022-09-21T08:52:46.000Z,2022-09-21T08:52:47.000Z,inist.sshade,mgeg,"mineral,natural terrestrial,phyllosilicate,Serpentine Rawhide,laboratory measurement,bidirectional reflection,macroscopic,Vis,Visible,NIR,Near-Infrared,reflectance factor","[{'subject': 'mineral'}, {'subject': 'natural terrestrial'}, {'subject': 'phyllosilicate'}, {'subject': 'Serpentine Rawhide'}, {'subject': 'laboratory measurement'}, {'subject': 'bidirectional reflection'}, {'subject': 'macroscopic'}, {'subject': 'Vis'}, {'subject': 'Visible'}, {'subject': 'NIR'}, {'subject': 'Near-Infrared'}, {'subject': 'reflectance factor'}]",['3 spectra'],['ASCII']
+10.5281/zenodo.10474604,MIPkit-W (MISOMIP2),Zenodo,2024.0,en,Dataset,Creative Commons Attribution 4.0 International,"Observational data kit gathered and reprocessed to facilitate the evaluation of ocean and ice-sheet simulations of the Weddell Sea sector as part of MISOMIP2.
+
+ 
+
+__________________________________________
+
+This entire dataset should be cited as:
+
+
+
+the MISOMIP2 MIPkit-W dataset (https://zenodo.org/doi/10.5281/zenodo.8316180) that includes data collected through multiple cruises of the Polarstern Research Vessel and originally provided by the Alfred Wegener Institute, Bremerhaven, Germany, and glaciological data from the MeaSUREs, MeaSUREs ITS_LIVE projects.
+
+
+For more specific use of some of the MIPkit-W data, we encourage people to cite the original data referenced below.
+
+ 
+
+__________________________________________
+
+IceSurfVel_MIPkitW_2000-2019 : annual maps of ice surface velocity
+
+Surface-parallel velocity vectors (in m/year) between 2000 and 2019 are provided on the common MISOMIP2 grid with regular grid spacing of 1 km. Data were calculated as a weighted average of all available Earth observation data from the MeaSUREs project (Rignot et al. 2014 and Mouginot et al. 2017) and MeaSUREs ITS_LIVE project (Gardner et al. 2022), with weights corresponding to the inverse square error of the original datasets. Propagated errors and a mask indicating the original data sources for each grid point are also included.
+
+ 
+
+__________________________________________
+
+IceSurfElChange_MIPkitW_1992-2019 : annual maps of surface elevation change
+
+Surface elevation changes (in m) between 1992 and 2019, relative to 16-Dec-2013, are provided on the common MISOMIP2 grid with regular grid spacing of 1 km. Data were calculated as a weighted average of available Earth observation data from MeaSUREs ITS_LIVE (Nilsson et al. 2023) for the grounded ice and MeaSUREs ITS_LIVE data (Paolo et al. 2023) for floating ice. Propagated errors and a mask indicating the original data sources for each grid point are also included.
+
+ 
+
+__________________________________________
+
+Oce3d_MIPkitW_* : 3-dimensional temperature and salinity (horizontal slices every 100m)
+
+The hydrographic properties provided on horizontal sections at 15 depths come from the CTD measurements obtained from late December to early March during the Alfred Wegener Institute Polarstern cruises ANT-XII/3 (Schroeder, 2010), PS82 (Schroeder, 2014), PS96 (Schroeder, 2016) and PS111 (Janout, 2019), which cover years 1995, 2014, 2016 and 2018, respectively.
+
+ 
+
+__________________________________________
+
+OceSec<n>_MIPkitW_* : vertical sections
+
+The first vertical section (OceSec1) goes from the tip of the Antartic Peninsula to Kapp Norvegia (12.33°E). It is known as WOCE-SR04 and has been monitored since 1989. The data provided were collected during Polarstern cruises in Sep.-Oct. 1989, Nov.-Dec. 1990, Dec. 1992-Jan. 1993, Mar.-May 1996, Apr.-May 1998 (Fahrbach and Rohardt, 1990, 1991, 1993, 1996, 1998), Jan.-Apr. 2005 (Rohardt 2010), Feb.-Apr. 2008 (Fahrbach and Rohardt, 2008), Dec. 2010-Jan. 2011 (Rohardt et al. 2011), Dec. 2012-Jan. 2013 (Rohardt 2013), as well as Dec. 2016-Jan. 2017 and Dec. 2018-Feb. 2019 (Rohardt and Boebel, 2017, 2020).
+
+The second vertical section (OceSec2) is at approximately 76°S and covers the eastern side of Filchner Through. It was surveyed during some of the Polarstern cruises on 5-8 Jan. 2014 (Schroeder, 2014), 20-24 Jan. 2016 (Schroeder, 2016) and 4-23 Feb. 2018 (Janout, 2019).
+
+The third and fourth sections were obtained along the front of Ronne (OceSec3) and Filchner (OceSec4) ice shelves, respectively. The Filchner section was measured on 1-3 Feb. 1977 by the Norwegian Antarctic Research Expedition with Research Vessel Polarsirkel (Foldvik et al., 1985), 7-16 Jan. 1981 (Hubold and Drescher, 1982), 25 Jan.- 4 Mar. 1995 (Schroeder, 2010), 15-17 Jan. 2014 (Schroeder, 2014), 15 Jan. 2016 (only one vertical profile; Schroeder, 2016), and 14-23 Feb. 2018 (Janout, 2019). The Ronne section was measured by some of these expeditions on 25 Jan.- 24 Feb. 1995, 14-15 Jan. 2016, and 9-14 Feb. 2018.
+
+The files OceSec<n>_MIPkitW_model_lon_lat.csv contain the coordinates (longitude, latitude) at which model data should be interpolated to be compared to the observational sections.
+
+ 
+
+__________________________________________
+
+OceMoor<n>_MIPkitW_* : moorings
+
+Temperature, salinity and velocity time series are provided at three moorings placed along the 76°S vertical section and referred to as OceMoor1 (AWI252, 30.47°W), OceMoor2 (AWI253, 30.99°W) and OceMoor3 (AWI254, 31.48°W), and cover the period from Jan. 2014 to Feb. 2018 (Schroeder et al., 2017a,b,c, 2019a,b,c). Temperature, salinity and velocity data were obtained at two depths for AWI252 (335 and 421 m depth for a seafloor at 447 m) and AWI253 (349 and 434 m depth for a seafloor at 456 m), while a single depth is provided for AWI254 (553 m for a seafloor at 581 m).
+
+ 
+
+__________________________________________
+
+The archive example_routines.zip  contains example of Matlab routines that were used to prepare the MIPkit-W ocean data, as well as GenerateData_MIPkit_Ice.m and writeNC_MIPkit_Ice.m that were used to process glaciological data.
+
+ 
+
+__________________________________________
+
+References
+
+Fahrbach, E. and Rohardt, G. (1990). Physical oceanography during POLARSTERN cruise ANT-VIII/2 (WWGS) on section SR02 and SR04, PANGAEA, https://doi.org/10.1594/PANGAEA.742580
+
+Fahrbach, E. and Rohardt, G. (1991). Physical oceanography during POLARSTERN cruise ANT-IX/2 on section SR04, PANGAEA, https://doi.org/10.1594/PANGAEA.735277
+
+Fahrbach, E. and Rohardt, G. (1993). Physical oceanography during POLARSTERN cruise ANT-X/7 on section SR04, PANGAEA, https://doi.org/10.1594/PANGAEA.742651
+
+Fahrbach, E. and Rohardt, G. (1996). Physical oceanography during POLARSTERN cruise ANT-XIII/4 on section S04A, PANGAEA, https://doi.org/10.1594/PANGAEA.738489
+
+Fahrbach, E. and Rohardt, G. (1998): Physical oceanography during POLARSTERN cruise ANT-XV/4 (DOVETAIL) on section SR04, PANGAEA, https://doi.org/10.1594/PANGAEA.742626
+
+Fahrbach, E. and Rohardt, G. (2008): Physical oceanography during POLARSTERN cruise ANT-XXIV/3, PANGAEA, https://doi.org/10.1594/PANGAEA.733414
+
+Foldvik, A,, Gammelsrød,T. & Tørresen, T. 1985: Hydrographic observations from the Weddell Sea during the Norwegian Antarctic Research Expedition 1976/77. Polar Research, 3:2, 177-193, https://doi.org/10.3402/polar.v3i2.6951
+
+Hubold, G. and Drescher, H. E. (1982). Die Filchner-Schelfeis-Expedition 1980/81 mit MS ""Polarsirkel"". Liste der Planktonfänge und Lichtstärkemessungen , Reports on Polar Research, Alfred Wegener Institute for Polar and Marine Research, Bremerhaven, 4, https://epic.awi.de/id/eprint/26181/1/BerPolarforsch19824.pdf
+
+Rohardt, G. (2010). Physical oceanography during POLARSTERN cruise ANT-XXII/3, https://doi.org/10.1594/PANGAEA.733664
+
+Rohardt, G. (2013). Physical oceanography during POLARSTERN cruise ANT-XXIX/2, https://doi.org/10.1594/PANGAEA.817255
+
+Rohardt, G. and Boebel, O. (2017). Physical oceanography during POLARSTERN cruise PS103 (ANT-XXXII/2), https://doi.org/10.1594/PANGAEA.881076
+
+Rohardt, G. and Boebel, O. (2020). Physical oceanography during POLARSTERN cruise PS117, https://doi.org/10.1594/PANGAEA.910663
+
+Rohardt, G., Fahrbach, E., and Wisotzki, A. (2011): Physical oceanography during POLARSTERN cruise ANT-XXVII/2, https://doi.org/10.1594/PANGAEA.772244
+
+Schröder, M. (2010). Physical oceanography during POLARSTERN cruise ANT-XII/3, https://doi.org/10.1594/PANGAEA.742581
+
+Schröder, M. and Wisotzki, A. (2014). Physical oceanography during POLARSTERN cruise PS82 (ANT-XXIX/9), https://doi.org/10.1594/PANGAEA.833299
+
+Schröder, M., Ryan, S., and Wisotzki, A. (2016). Physical oceanography during POLARSTERN cruise PS96 (ANT-XXXI/2 FROSN), https://doi.org/10.1594/PANGAEA.859040
+
+Schröder, M., Ryan, S., and Wisotzki, A. (2017a). Physical oceanography and current meter data from mooring AWI252-1, https://doi.org/10.1594/PANGAEA.875931
+
+Schröder, M., Ryan, S., and Wisotzki, A. (2017b). Physical oceanography and current meter data from mooring AWI253-1, https://doi.org/10.1594/PANGAEA.875932
+
+Schröder, M., Ryan, S., and Wisotzki, A. (2017c). Physical oceanography and current meter data from mooring AWI254-1, https://doi.org/10.1594/PANGAEA.875933
+
+Schröder, M., Ryan, S., and Wisotzki, A. (2019a). Physical oceanography and current meter data from mooring AWI252-2, https://doi.org/10.1594/PANGAEA.903104
+
+Schröder, M., Ryan, S., and Wisotzki, A. (2019b). Physical oceanography and current meter data from mooring AWI253-2, https://doi.org/10.1594/PANGAEA.903315
+
+Schröder, M., Ryan, S., and Wisotzki, A. (2019c). Physical oceanography and current meter data from mooring AWI254-2, https://doi.org/10.1594/PANGAEA.903317",api,True,findable,0.0,0.0,0.0,0.0,0.0,2024-01-09T14:50:26.000Z,2024-01-09T14:50:26.000Z,cern.zenodo,cern,"Weddell Sea,Ocean model,Antarctica,MISOMIP","[{'subject': 'Weddell Sea'}, {'subject': 'Ocean model'}, {'subject': 'Antarctica'}, {'subject': 'MISOMIP'}]",,
+10.26302/sshade/experiment_bs_20121219_001,Near-IR bidirectional reflection spectra (i=0°/e=30°) of Palagonite JSC Mars-1 with different amounts of adsorbed H2O at -30°C,SSHADE/GhoSST (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","Near-IR bidirectional reflection spectra (at fixed geometry: i=0°/e=30°) of Palagonite JSC Mars-1 simulant with different amounts of adsorbed H2O at -30°C, under increasing, then decreasing pressure of H2O vapor.",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2019-11-02T10:47:31.000Z,2019-11-02T10:47:32.000Z,inist.sshade,mgeg,"solid,natural terrestrial,oxide-hydroxide,Magnetite,Ulvospinel,tektosilicate,Anorthite,nesosilicate,Olivine,Ferrihydrite,inosilicate,Augite,Orthopyroxenes,physically adsorbed phase,Adsorbed - Interlayer H2O,laboratory measurement,bidirectional reflection,macroscopic,NIR,Near-Infrared,reflectance factor","[{'subject': 'solid'}, {'subject': 'natural terrestrial'}, {'subject': 'oxide-hydroxide'}, {'subject': 'Magnetite'}, {'subject': 'Ulvospinel'}, {'subject': 'tektosilicate'}, {'subject': 'Anorthite'}, {'subject': 'nesosilicate'}, {'subject': 'Olivine'}, {'subject': 'Ferrihydrite'}, {'subject': 'inosilicate'}, {'subject': 'Augite'}, {'subject': 'Orthopyroxenes'}, {'subject': 'physically adsorbed phase'}, {'subject': 'Adsorbed - Interlayer H2O'}, {'subject': 'laboratory measurement'}, {'subject': 'bidirectional reflection'}, {'subject': 'macroscopic'}, {'subject': 'NIR'}, {'subject': 'Near-Infrared'}, {'subject': 'reflectance factor'}]",['36 spectra'],['ASCII']
+10.26302/sshade/experiment_ct_20090317_001,NIR reflectance spectra of water ice with varying grain size and temperature,SSHADE/SSTONE (OSUG Data Center),2019.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","An experimental facility has been set up to acquire infrared spectra of pure water ices with controlled grain sizes ranging from 80 to 700 µm and temperatures ranging from 80 to 140 K at 0.01 mbar. Forty-seven near IR spectra (1.0–5.0 µm), selected among the total acquired spectra, permit us to determine how spectral characteristics between 1.0 and 1.8 µm depend on both grain size and temperature.",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2019-11-01T08:20:43.000Z,2019-11-01T08:20:43.000Z,inist.sshade,mgeg,"laboratory,inorganic molecular solid,Crystalline H2O ice,laboratory measurement,bidirectional reflection,macroscopic,NIR,Near-Infrared,bidirectional reflectance","[{'subject': 'laboratory'}, {'subject': 'inorganic molecular solid'}, {'subject': 'Crystalline H2O ice'}, {'subject': 'laboratory measurement'}, {'subject': 'bidirectional reflection'}, {'subject': 'macroscopic'}, {'subject': 'NIR'}, {'subject': 'Near-Infrared'}, {'subject': 'bidirectional reflectance'}]",['224 spectra'],['ASCII']
+10.26302/sshade/experiment_lb_20191211_002,Fe K edge XAS transmission of bulk heated CM carbonaceous chondrites,SSHADE/GhoSST+FAME (OSUG Data Center),2020.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",raw and normalized Fe K edge XAS transmission of bulk heated CM carbonaceous chondrites,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2019-12-13T13:04:26.000Z,2019-12-13T13:04:27.000Z,inist.sshade,mgeg,"solid,commercial,non-oxide ceramic,BN powder,extraterrestrial,carbonaceous chondrite,CM,complex organic-mineral mix,matrix QUE93005 IPAG,complex mineral mix,chondrules QUE93005 IPAG,CAIs QUE93005 IPAG,matrix ALH84033 IPAG,chondrules ALH84033 IPAG,CAIs ALH84033 IPAG,matrix DOM03183 IPAG,chondrules DOM03183 IPAG,CAIs DOM03183 IPAG,ungrouped chondrite,ungrouped,matrix EET83355 IPAG,chondrules EET83355 IPAG,CAIs EET83355 IPAG,matrix EET96029 IPAG,chondrules EET96029 IPAG,CAIs EET96029 IPAG,matrix EET87522 IPAG,chondrules EET87522 IPAG,CAIs EET87522 IPAG,matrix MAC88100 IPAG,chondrules MAC88100 IPAG,CAIs MAC88100 IPAG,matrix MIL07700 IPAG,chondrules MIL07700 IPAG,CAIs MIL07700 IPAG,matrix PCA02010 IPAG,chondrules PCA02010 IPAG,CAIs PCA02010 IPAG,matrix PCA02012 IPAG,chondrules PCA02012 IPAG,CAIs PCA02012 IPAG,matrix PCA91008 IPAG,chondrules PCA91008 IPAG,CAIs PCA91008 IPAG,matrix WIS91600 IPAG,chondrules WIS91600 IPAG,CAIs WIS91600 IPAG,laboratory measurement,transmission,None,hard X,raw,normalized absorbance","[{'subject': 'solid'}, {'subject': 'commercial'}, {'subject': 'non-oxide ceramic'}, {'subject': 'BN powder'}, {'subject': 'extraterrestrial'}, {'subject': 'carbonaceous chondrite'}, {'subject': 'CM'}, {'subject': 'complex organic-mineral mix'}, {'subject': 'matrix QUE93005 IPAG'}, {'subject': 'complex mineral mix'}, {'subject': 'chondrules QUE93005 IPAG'}, {'subject': 'CAIs QUE93005 IPAG'}, {'subject': 'matrix ALH84033 IPAG'}, {'subject': 'chondrules ALH84033 IPAG'}, {'subject': 'CAIs ALH84033 IPAG'}, {'subject': 'matrix DOM03183 IPAG'}, {'subject': 'chondrules DOM03183 IPAG'}, {'subject': 'CAIs DOM03183 IPAG'}, {'subject': 'ungrouped chondrite'}, {'subject': 'ungrouped'}, {'subject': 'matrix EET83355 IPAG'}, {'subject': 'chondrules EET83355 IPAG'}, {'subject': 'CAIs EET83355 IPAG'}, {'subject': 'matrix EET96029 IPAG'}, {'subject': 'chondrules EET96029 IPAG'}, {'subject': 'CAIs EET96029 IPAG'}, {'subject': 'matrix EET87522 IPAG'}, {'subject': 'chondrules EET87522 IPAG'}, {'subject': 'CAIs EET87522 IPAG'}, {'subject': 'matrix MAC88100 IPAG'}, {'subject': 'chondrules MAC88100 IPAG'}, {'subject': 'CAIs MAC88100 IPAG'}, {'subject': 'matrix MIL07700 IPAG'}, {'subject': 'chondrules MIL07700 IPAG'}, {'subject': 'CAIs MIL07700 IPAG'}, {'subject': 'matrix PCA02010 IPAG'}, {'subject': 'chondrules PCA02010 IPAG'}, {'subject': 'CAIs PCA02010 IPAG'}, {'subject': 'matrix PCA02012 IPAG'}, {'subject': 'chondrules PCA02012 IPAG'}, {'subject': 'CAIs PCA02012 IPAG'}, {'subject': 'matrix PCA91008 IPAG'}, {'subject': 'chondrules PCA91008 IPAG'}, {'subject': 'CAIs PCA91008 IPAG'}, {'subject': 'matrix WIS91600 IPAG'}, {'subject': 'chondrules WIS91600 IPAG'}, {'subject': 'CAIs WIS91600 IPAG'}, {'subject': 'laboratory measurement'}, {'subject': 'transmission'}, {'subject': 'None'}, {'subject': 'hard X'}, {'subject': 'raw'}, {'subject': 'normalized absorbance'}]",['24 spectra'],['ASCII']
+10.26302/sshade/bandlist_abs_c2n2-c2n2-i,Absorption band list of C2N2 in natural solid C2N2 (phase I),SSHADE/BANDLIST (OSUG Data Center),2021.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",MIR-FIR absorption band list of $C_2N_2$ in natural solid $C_2N_2$ (phase I) between 20 and 95 K,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-04-21T06:59:28.000Z,2023-04-21T06:59:29.000Z,inist.sshade,mgeg,"natural C2N2 - phase I,Cyanogen,Cyanogen phase I,C2N2 Phase I,Ethanedinitrile,460-19-5,C2N2,non polar molecular solid,molecular solids with apolar molecules,organic molecular solid,absorption,FIR,MIR,band frequency,band width,band intensity,transition and vibration modes","[{'subject': 'natural C2N2 - phase I', 'subjectScheme': 'name'}, {'subject': 'Cyanogen', 'subjectScheme': 'name'}, {'subject': 'Cyanogen phase I', 'subjectScheme': 'name'}, {'subject': 'C2N2 Phase I', 'subjectScheme': 'name'}, {'subject': 'Ethanedinitrile', 'subjectScheme': 'IUPAC name'}, {'subject': '460-19-5', 'subjectScheme': 'CAS number'}, {'subject': 'C2N2', 'subjectScheme': 'formula'}, {'subject': 'non polar molecular solid', 'subjectScheme': 'class'}, {'subject': 'molecular solids with apolar molecules', 'subjectScheme': 'class'}, {'subject': 'organic molecular solid', 'subjectScheme': 'compound type'}, {'subject': 'absorption', 'subjectScheme': 'var'}, {'subject': 'FIR', 'subjectScheme': 'var'}, {'subject': 'MIR', 'subjectScheme': 'var'}, {'subject': 'band frequency', 'subjectScheme': 'var'}, {'subject': 'band width', 'subjectScheme': 'var'}, {'subject': 'band intensity', 'subjectScheme': 'var'}, {'subject': 'transition and vibration modes', 'subjectScheme': 'var'}]",,['ASCII']
+10.26302/sshade/experiment_rc_20200511_000,VIS-NIR reflectance spectra collected during low-temperature and near-vacuum sublimation of spherical salty ice particles (67 µm average diameter) produced by freezing droplets of solutions of Na2SO4 with three different concentrations,SSHADE/BYPASS (OSUG Data Center),2023.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",Spherical ice particles are produced by spraying droplets of salt solution into liquid nitrogen with the SPIPA-B setup. Centimeter-thick samples made of these particles are then introduced in the SCITEAS-2 simulations chamber and their slow sublimation at low temperature and in secondary vacuum is followed for several tens of hours by VIS-NIR hyperspectral imaging.,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-06-09T17:14:52.000Z,2023-06-09T17:14:53.000Z,inist.sshade,mgeg,"laboratory measurement,biconical reflection,imaging,Vis,Visible,NIR,Near-Infrared,reflectance factor,water ice,Sodium sulfate hydrates,laboratory,inorganic molecular solid,sulfate","[{'subject': 'laboratory measurement', 'subjectScheme': 'main'}, {'subject': 'biconical reflection', 'subjectScheme': 'main'}, {'subject': 'imaging', 'subjectScheme': 'main'}, {'subject': 'Vis', 'subjectScheme': 'variables'}, {'subject': 'Visible', 'subjectScheme': 'variables'}, {'subject': 'NIR', 'subjectScheme': 'variables'}, {'subject': 'Near-Infrared', 'subjectScheme': 'variables'}, {'subject': 'reflectance factor', 'subjectScheme': 'variables'}, {'subject': 'water ice', 'subjectScheme': 'name'}, {'subject': 'Sodium sulfate hydrates', 'subjectScheme': 'name'}, {'subject': 'laboratory', 'subjectScheme': 'origin'}, {'subject': 'inorganic molecular solid', 'subjectScheme': 'compound type'}, {'subject': 'sulfate', 'subjectScheme': 'compound type'}]",['184 spectra'],['ASCII']
+10.15778/resif.ze2018,Passive temporary dense network in Quito City (Ecuador) for site-city interaction (RESIF - SISMOB),RESIF - Réseau Sismologique et géodésique Français,2019.0,en,Dataset,"Open Access,Creative Commons Attribution 4.0 International","In the META-City Quito experiment, we expect to accurately measure the effect of the resonators array composed by civil engineering structures on the seismic wave field, in the manner of an urban meta-material. Recent applications in the field of physics, acoustics and recently geophysics have shown the existence of forbidden bands, that is, frequencies in which the seismic energy disappears. This concept could help to understand the heterogeneous distribution of damage in urban areas as well as to imagine seismic-proof cities as a result of the distribution and design of structures.",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2019-08-16T10:02:39.000Z,2019-08-16T10:03:48.000Z,inist.resif,vcob,"urban seismology,site-city interaction,Meta-City Quito,Ecuador,Seismic risk","[{'subject': 'urban seismology'}, {'subject': 'site-city interaction'}, {'subject': 'Meta-City Quito'}, {'subject': 'Ecuador'}, {'subject': 'Seismic risk'}]",['24 Gb;42 stations'],"['miniseed data', 'stationXML metadata']"
+10.26302/sshade/experiment_dt_20180117_002,Cu K edge XAS transmission of Cu metallic foil reference at ambient conditions,SSHADE/FAME (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2019-11-16T07:51:36.000Z,2019-11-16T07:51:36.000Z,inist.sshade,mgeg,"commercial,elemental solid,metallic Cu,laboratory measurement,transmission,None,hard X,hard X-rays","[{'subject': 'commercial'}, {'subject': 'elemental solid'}, {'subject': 'metallic Cu'}, {'subject': 'laboratory measurement'}, {'subject': 'transmission'}, {'subject': 'None'}, {'subject': 'hard X'}, {'subject': 'hard X-rays'}]",['1 spectrum'],['ASCII']
+10.6084/m9.figshare.23994604,Additional file 2 of Determination of different social groups’ level of knowledge about malaria in a multicultural Amazonian cross-border context,figshare,2023.0,,Text,Creative Commons Attribution 4.0 International,Additional file 2: Appendix 2. Factor analyses of multiple-choice variables assessing knowledge of malaria prevention methods,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-08-20T03:11:03.000Z,2023-08-20T03:11:03.000Z,figshare.ars,otjm,"Biological Sciences not elsewhere classified,Science Policy","[{'subject': 'Biological Sciences not elsewhere classified'}, {'subject': 'Science Policy'}]",['20317 Bytes'],
+10.26302/sshade/experiment_lb_20201001_001,"Raw MIR transmission spectra of matrix fragments of CO chondrites, pressed on diamonds under vacuum and at several temperatures",SSHADE/GhoSST (OSUG Data Center),2022.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","MIR spectra of several matrix fragments of DOM 08006, MIL 07687, LAP 031117, DOM 03238, and Kainsaz CO chondrites under vacuum and at ambient temperature, 100°C and 300°C",mds,True,findable,0.0,0.0,0.0,1.0,0.0,2022-10-13T13:26:37.000Z,2022-10-13T13:26:37.000Z,inist.sshade,mgeg,"extraterrestrial,complex organic-mineral mix,matrix DOM08006,physically adsorbed phase,adsorbed phase,matrix MIL07687,matrix LAP031117,matrix DOM03238,matrix Kainsaz,laboratory measurement,transmission,microscopy,MIR,Mid-Infrared,absorbance","[{'subject': 'extraterrestrial'}, {'subject': 'complex organic-mineral mix'}, {'subject': 'matrix DOM08006'}, {'subject': 'physically adsorbed phase'}, {'subject': 'adsorbed phase'}, {'subject': 'matrix MIL07687'}, {'subject': 'matrix LAP031117'}, {'subject': 'matrix DOM03238'}, {'subject': 'matrix Kainsaz'}, {'subject': 'laboratory measurement'}, {'subject': 'transmission'}, {'subject': 'microscopy'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'absorbance'}]",['68 spectra'],['ASCII']
+10.5281/zenodo.10519316,Revealing trends in extreme heatwave intensity: Applying the UNSEEN approach to Nordic countries - Supplementary Material,Zenodo,2024.0,,Other,Creative Commons Attribution 4.0 International,"16/01/2024sberghaldsebastian.berghald@etu.univ-grenoble-alpes.fr
+
+In this folder we gathered some additional material to our paper on UNSEEN applied to heatwaves in Northern Europe. You will find:
+
+- Codes:    - Jupyter code used to compute region-averaged timeseries of both UNSEEN ensemble and reanalysis data. For downloading data from Copernicus CDS please refer to Timo Kelder's codes: https://unseen-open.readthedocs.io/en/latest/index.html    - R markdown file including all the statistical analysis of the timeseries obtained from the jupyter code.- Data:    - Gridded netCDF files of 3day running mean Tmax for both SEAS5 ensemble and MET Nordic LTC (based on NORA3 reanalysis). Archived SEAS5 seasonal forecast data are available at ECMWF MARS archive: https://apps.ecmwf.int/mars-catalogue/ . Description and availability of the MET Nordic long-term consistent product can be found at MET Norway's Github pages: https://github.com/metno/NWPdocs/wiki/MET-Nordic-dataset .    - Gridded MJJ 2m temperature, mean for each year (also SEAS5).    - Modified NUTS regions. Shapefiles of the NUTS dataset are available from Eurostat's webpages: https://ec.europa.eu/eurostat/web/gisco/geodata/reference-data/administrative-units-statistical-units- Figures:       The figures included in the paper as well as supplementary figures in high resolution.- Results:    - Notebooks for all regions containing the detailed analysis with all the 'usual' (from UNSEEN-open) UNSEEN plots, return period plots, probability calculations etc.    - An Excel-spreadsheet containing many of the resulting values. The maps were plotted on this basis.",api,True,findable,0.0,0.0,0.0,0.0,0.0,2024-01-16T15:20:03.000Z,2024-01-16T15:20:03.000Z,cern.zenodo,cern,,,,
+10.26302/sshade/experiment_gm_20220122,Raman spectra of some chlorate minerals,SSHADE/REAP (OSUG Data Center),2022.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,1.0,0.0,2022-01-22T15:02:21.000Z,2022-01-22T15:02:22.000Z,inist.sshade,mgeg,"commercial,perchlorate,Sodium perchlorate hydrate,Calcium perchlorate tetrahydrate,laboratory measurement,Raman scattering,microscopy,MIR,Mid-Infrared,FIR,Far-Infrared,normalized Raman scattering intensity","[{'subject': 'commercial'}, {'subject': 'perchlorate'}, {'subject': 'Sodium perchlorate hydrate'}, {'subject': 'Calcium perchlorate tetrahydrate'}, {'subject': 'laboratory measurement'}, {'subject': 'Raman scattering'}, {'subject': 'microscopy'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'FIR'}, {'subject': 'Far-Infrared'}, {'subject': 'normalized Raman scattering intensity'}]",['2 spectra'],['ASCII']
+10.6084/m9.figshare.c.6596467,"A multicentre, patient- and assessor-blinded, non-inferiority, randomised and controlled phase II trial to compare standard and torque teno virus-guided immunosuppression in kidney transplant recipients in the first year after transplantation: TTVguideIT",figshare,2023.0,,Collection,Creative Commons Attribution 4.0 International,"Abstract Background Immunosuppression after kidney transplantation is mainly guided via plasma tacrolimus trough level, which cannot sufficiently predict allograft rejection and infection. The plasma load of the non-pathogenic and highly prevalent torque teno virus (TTV) is associated with the immunosuppression of its host. Non-interventional studies suggest the use of TTV load to predict allograft rejection and infection. The primary objective of the current trial is to demonstrate the safety, tolerability and preliminary efficacy of TTV-guided immunosuppression. Methods For this purpose, a randomised, controlled, interventional, two-arm, non-inferiority, patient- and assessor-blinded, investigator-driven phase II trial was designed. A total of 260 stable, low-immunological-risk adult recipients of a kidney graft with tacrolimus-based immunosuppression and TTV infection after month 3 post-transplantation will be recruited in 13 academic centres in six European countries. Subjects will be randomised in a 1:1 ratio (allocation concealment) to receive tacrolimus either guided by TTV load or according to the local centre standard for 9 months. The primary composite endpoint includes the occurrence of infections, biopsy-proven allograft rejection, graft loss, or death. The main secondary endpoints include estimated glomerular filtration rate, graft rejection detected by protocol biopsy at month 12 post-transplantation (including molecular microscopy), development of de novo donor-specific antibodies, health-related quality of life, and drug adherence. In parallel, a comprehensive biobank will be established including plasma, serum, urine and whole blood. The date of the first enrolment was August 2022 and the planned end is April 2025. Discussion The assessment of individual kidney transplant recipient immune function might enable clinicians to personalise immunosuppression, thereby reducing infection and rejection. Moreover, the trial might act as a proof of principle for TTV-guided immunosuppression and thus pave the way for broader clinical applications, including as guidance for immune modulators or disease-modifying agents. Trial registration EU CT-Number: 2022-500024-30-00",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-04-13T16:10:08.000Z,2023-04-13T17:26:49.000Z,figshare.ars,otjm,"Immunology,FOS: Clinical medicine","[{'subject': 'Immunology'}, {'subject': 'FOS: Clinical medicine', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}]",,
+10.15778/resif.yp2014,Seismic network YP:French part of the Argostoli (Greece) aftershock experiment (RESIF-SISMOB),RESIF - Réseau Sismologique et géodésique Français,2014.0,en,Dataset,"Open Access,Creative Commons Attribution 4.0 International","Within the framework of the JRA1 work packages (Waveform modelling and site coefficients for basin response and topography) of the FP7 EU-NERA 2010-2014 project (Network of European Research Infrastructures for Earthquake Risk Assessment and Mitigation), a dense seismological temporary network was deployed in the Argostoli sedimentary basin (Cephalonia island, Greece) in order to investigate basin effects and spatial variation of ground motion. Tooking place during the period September 15th, 2011 to April 20th, 2012, the seismological experiment comprised 62 seismological stations (mid-band velocimeters, eventually coupled with accelerometers) deployed across the Argostoli basin with inter-station of about 50 meters. 2 mid-band velocimeters were installed at the eastern- and western-most part of the island in order to improve hypocentral location of earthquakes recorded during the experiment. Finally, two dense seismic arrays (with inter-station distance from 5 m to 160 m) were also deployed inside the basin to thoroughly understand seismic wave field composition. More than 3000 seismic events were recorded by this seismological network, among which 817 event with a signal-to-noise ratio above 3.",mds,True,findable,0.0,0.0,0.0,6.0,0.0,2020-04-02T14:31:27.000Z,2020-04-02T14:32:20.000Z,inist.resif,vcob,"dense array,site effects,spatial variability","[{'subject': 'dense array'}, {'subject': 'site effects'}, {'subject': 'spatial variability'}]",['57 Gb;8 stations'],"['miniseed data', 'stationXML metadata']"
+10.26302/sshade/experiment_tg_20181312_001,UV-Vis optical indices of 3 oxygenated Tholins films,SSHADE/SPAN (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","Set of UV-Visible (270-600nm) optical indices of tholins films formed with different $CH_4$ and $CO_2$ percentages in $N_2$ gas: 5%:0%, 5%:5%, 5%:8%",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-04-20T18:06:18.000Z,2023-04-20T18:06:19.000Z,inist.sshade,mgeg,"laboratory measurement,ellipsometry,macroscopic,UV,Ultraviolet,Vis,Visible,optical constants,OxyTholins LATMOS Film 95%N2:0%CO2:5%CH4,OxyTholins LATMOS Film 90%N2:5%CO2:5%CH4,laboratory,complex macromolecular mixture","[{'subject': 'laboratory measurement', 'subjectScheme': 'main'}, {'subject': 'ellipsometry', 'subjectScheme': 'main'}, {'subject': 'macroscopic', 'subjectScheme': 'main'}, {'subject': 'UV', 'subjectScheme': 'var'}, {'subject': 'Ultraviolet', 'subjectScheme': 'var'}, {'subject': 'Vis', 'subjectScheme': 'var'}, {'subject': 'Visible', 'subjectScheme': 'var'}, {'subject': 'optical constants', 'subjectScheme': 'var'}, {'subject': 'OxyTholins LATMOS Film 95%N2:0%CO2:5%CH4', 'subjectScheme': 'name'}, {'subject': 'OxyTholins LATMOS Film 90%N2:5%CO2:5%CH4', 'subjectScheme': 'name'}, {'subject': 'laboratory', 'subjectScheme': 'origin'}, {'subject': 'complex macromolecular mixture', 'subjectScheme': 'compound type'}]",['3 spectra'],['ASCII']
+10.26302/sshade/bandlist_raman_alpha_k2caco3-2,Raman bandlist of synthetic alpha-K2Ca(CO3)2 (Bütschliite),SSHADE/BANDLIST (OSUG Data Center),2023.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",MIR-FIR Raman bandlist of synthetic $\alpha-K_2Ca(CO_3)_2$ (Bütschliite) at 295K,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-09-10T17:21:02.000Z,2023-09-10T17:21:03.000Z,inist.sshade,mgeg,"$K_2Ca(CO_3)_2$ - phase alpha,Potassium(1+) cation,Calcium cation,Carbonate anion,alpha Dipotassium calcium carbonate,$\alpha-K_2Ca(CO_3)_2$,Potassium cation,Calcium(2+) cation,24203-36-9,14127-61-8,K+,Ca2+,(CO3)2-,K2Ca(CO3)2,normal salt,normal salts,carbonate,Raman scattering,FIR,MIR,band frequency,band width,band intensity,transition and vibration modes","[{'subject': '$K_2Ca(CO_3)_2$ - phase alpha', 'subjectScheme': 'name'}, {'subject': 'Potassium(1+) cation', 'subjectScheme': 'name'}, {'subject': 'Calcium cation', 'subjectScheme': 'name'}, {'subject': 'Carbonate anion', 'subjectScheme': 'name'}, {'subject': 'alpha Dipotassium calcium carbonate', 'subjectScheme': 'name'}, {'subject': '$\\alpha-K_2Ca(CO_3)_2$', 'subjectScheme': 'name'}, {'subject': 'Potassium cation', 'subjectScheme': 'IUPAC name'}, {'subject': 'Calcium(2+) cation', 'subjectScheme': 'IUPAC name'}, {'subject': '24203-36-9', 'subjectScheme': 'CAS number'}, {'subject': '14127-61-8', 'subjectScheme': 'CAS number'}, {'subject': 'K+', 'subjectScheme': 'formula'}, {'subject': 'Ca2+', 'subjectScheme': 'formula'}, {'subject': '(CO3)2-', 'subjectScheme': 'formula'}, {'subject': 'K2Ca(CO3)2', 'subjectScheme': 'formula'}, {'subject': 'normal salt', 'subjectScheme': 'class'}, {'subject': 'normal salts', 'subjectScheme': 'class'}, {'subject': 'carbonate', 'subjectScheme': 'compound type'}, {'subject': 'Raman scattering', 'subjectScheme': 'variables'}, {'subject': 'FIR', 'subjectScheme': 'variables'}, {'subject': 'MIR', 'subjectScheme': 'variables'}, {'subject': 'band frequency', 'subjectScheme': 'variables'}, {'subject': 'band width', 'subjectScheme': 'variables'}, {'subject': 'band intensity', 'subjectScheme': 'variables'}, {'subject': 'transition and vibration modes', 'subjectScheme': 'variables'}]",,['ASCII']
+10.6084/m9.figshare.23575369,Additional file 4 of Decoupling of arsenic and iron release from ferrihydrite suspension under reducing conditions: a biogeochemical model,figshare,2023.0,,Text,Creative Commons Attribution 4.0 International,Authors’ original file for figure 3,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-06-25T03:11:48.000Z,2023-06-25T03:11:49.000Z,figshare.ars,otjm,"59999 Environmental Sciences not elsewhere classified,FOS: Earth and related environmental sciences,39999 Chemical Sciences not elsewhere classified,FOS: Chemical sciences,Ecology,FOS: Biological sciences,69999 Biological Sciences not elsewhere classified,Cancer","[{'subject': '59999 Environmental Sciences not elsewhere classified', 'schemeUri': 'http://www.abs.gov.au/ausstats/abs@.nsf/0/6BB427AB9696C225CA2574180004463E', 'subjectScheme': 'FOR'}, {'subject': 'FOS: Earth and related environmental sciences', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': '39999 Chemical Sciences not elsewhere classified', 'schemeUri': 'http://www.abs.gov.au/ausstats/abs@.nsf/0/6BB427AB9696C225CA2574180004463E', 'subjectScheme': 'FOR'}, {'subject': 'FOS: Chemical sciences', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': 'Ecology'}, {'subject': 'FOS: Biological sciences', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': '69999 Biological Sciences not elsewhere classified', 'schemeUri': 'http://www.abs.gov.au/ausstats/abs@.nsf/0/6BB427AB9696C225CA2574180004463E', 'subjectScheme': 'FOR'}, {'subject': 'Cancer'}]",['45056 Bytes'],
+10.6084/m9.figshare.c.6583718,TRansfusion strategies in Acute brain INjured patients (TRAIN): a prospective multicenter randomized interventional trial protocol,figshare,2023.0,,Collection,Creative Commons Attribution 4.0 International,"Abstract Background Although blood transfusions can be lifesaving in severe hemorrhage, they can also have potential complications. As anemia has also been associated with poor outcomes in critically ill patients, determining an optimal transfusion trigger is a real challenge for clinicians. This is even more important in patients with acute brain injury who were not specifically evaluated in previous large randomized clinical trials. Neurological patients may be particularly sensitive to anemic brain hypoxia because of the exhausted cerebrovascular reserve, which adjusts cerebral blood flow to tissue oxygen demand. Methods We described herein the methodology of a prospective, multicenter, randomized, pragmatic trial comparing two different strategies for red blood cell transfusion in patients with acute brain injury: a “liberal” strategy in which the aim is to maintain hemoglobin (Hb) concentrations greater than 9 g/dL and a “restrictive” approach in which the aim is to maintain Hb concentrations greater than 7 g/dL. The target population is patients suffering from traumatic brain injury (TBI), subarachnoid hemorrhage (SAH), or intracerebral hemorrhage (ICH). The primary outcome is the unfavorable neurological outcome, evaluated using the extended Glasgow Outcome Scale (eGOS) of 1–5 at 180 days after the initial injury. Secondary outcomes include, among others, 28-day survival, intensive care unit (ICU) and hospital lengths of stay, the occurrence of extra-cerebral organ dysfunction/failure, and the development of any infection or thromboembolic events. The estimated sample size is 794 patients to demonstrate a reduction in the primary outcome from 50 to 39% between groups (397 patients in each arm). The study was initiated in 2016 in several ICUs and will be completed in December 2022. Discussion This trial will assess the impact of a liberal versus conservative strategy of blood transfusion in a large cohort of critically ill patients with a primary acute brain injury. The results of this trial will help to improve blood product and transfusion use in this specific patient population and will provide additional data in some subgroups of patients at high risk of brain ischemia, such as those with intracranial hypertension or cerebral vasospasm. Trial registration ClinicalTrials.gov NCT02968654.",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-04-13T11:34:57.000Z,2023-04-13T11:34:57.000Z,figshare.ars,otjm,"Medicine,Cell Biology,Neuroscience,Biotechnology,Immunology,FOS: Clinical medicine,69999 Biological Sciences not elsewhere classified,FOS: Biological sciences,Cancer,110309 Infectious Diseases,FOS: Health sciences","[{'subject': 'Medicine'}, {'subject': 'Cell Biology'}, {'subject': 'Neuroscience'}, {'subject': 'Biotechnology'}, {'subject': 'Immunology'}, {'subject': 'FOS: Clinical medicine', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': '69999 Biological Sciences not elsewhere classified', 'schemeUri': 'http://www.abs.gov.au/ausstats/abs@.nsf/0/6BB427AB9696C225CA2574180004463E', 'subjectScheme': 'FOR'}, {'subject': 'FOS: Biological sciences', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': 'Cancer'}, {'subject': '110309 Infectious Diseases', 'schemeUri': 'http://www.abs.gov.au/ausstats/abs@.nsf/0/6BB427AB9696C225CA2574180004463E', 'subjectScheme': 'FOR'}, {'subject': 'FOS: Health sciences', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}]",,
+10.26302/sshade/experiment_bs_20201114_009,"Near-infrared reflectance spectra at low temperature (300-90K) of Larderellite [(NH4)B5O7(OH)2·H2O] powders with three grain size ranges (32-80, 80-125 and 125-150µm)",SSHADE/CSS (OSUG Data Center),2022.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",Near-infrared reflectance spectra at low temperature (297-90K) of Larderellite powder [(NH4)B5O7(OH)2.H2O] with 32-80 µm grain size and at room temperature with 80-125µm and 125-150µm grain sizes,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2022-04-23T08:17:40.000Z,2022-04-23T08:17:41.000Z,inist.sshade,mgeg,"natural terrestrial,borate,Larderellite,laboratory measurement,bidirectional reflection,macroscopic,NIR,Near-Infrared,reflectance factor","[{'subject': 'natural terrestrial'}, {'subject': 'borate'}, {'subject': 'Larderellite'}, {'subject': 'laboratory measurement'}, {'subject': 'bidirectional reflection'}, {'subject': 'macroscopic'}, {'subject': 'NIR'}, {'subject': 'Near-Infrared'}, {'subject': 'reflectance factor'}]",['14 spectra'],['ASCII']
+10.15778/resif.zf2015,"Rivière des Pluies Project, La Réunion Island, 2015-2018",RESIF - Réseau Sismologique et géodésique Français,2015.0,en,Dataset,"Open Access,Creative Commons Attribution 4.0 International","In the frame of the Rivière des Pluies project, a temporary seismic network of approximately 10 three-component broadband seismometers was deployed around two rivers of La Réunion Island: Rivière des Pluies and Rivière du Mât. The goal of the project is to monitor spatial and temporal variations of the river’s bed-load during tropical cyclones with high-frequency noise.",mds,True,findable,0.0,0.0,0.0,1.0,0.0,2016-08-08T15:01:38.000Z,2016-08-08T15:01:38.000Z,inist.resif,vcob,Monitoring the transport of sediment during tropical cyclones from high-frequency seismic noise in two rivers of La Réunion Island,[{'subject': 'Monitoring the transport of sediment during tropical cyclones from high-frequency seismic noise in two rivers of La Réunion Island'}],"['10 stations, 155 Gb per year, growing']","['Miniseed data data', 'stationXML metadata']"
+10.5281/zenodo.10485583,"Fig. 6 in The chloroplast membrane associated ceQORH putative quinone oxidoreductase reduces long-chain, stress-related oxidized lipids",Zenodo,2016.0,,Image,License Not Specified,"Fig. 6. Characterization of ceQORH properties with long-chain Oi,β-unsaturated ketone with a oxygenated substituent in position γ. (A) ceQORH activity as a function of trans- 1,4-diphenyl-2-butene-1,4-dione concentration. k is 5.5 ± 0.6 s –1, K is 14 ± 3.5 µM. (B) As a function of trans-EKODE(E)-IB concentration. k is 0.5 ± 0.1 s –1, K is 3 ± 1 µM. cat M cat M (C) As a function of Ƴ-ketol 18:1 concentration. k is 6 ± 0.4 s –1, K is 14 ± 3 µM. (D) As a function of Ƴ-ketol-18:2 concentration. k is 3 ± 0.34 s –1, K is 10 ± 3 µM. (E) cat M cat M ceQORH activity as a function of 10-keto-9,13-diol concentration. k is 0.2 ± 0.03 s –1, K is 3 ± 1.4 µM. (F) ceQORH activity as a function of traumatin concentration; The cat M apparent affinity was too low to measure KM and kcat parameters (see Table 1).",api,True,findable,0.0,0.0,0.0,0.0,0.0,2024-01-11T04:59:46.000Z,2024-01-11T04:59:46.000Z,cern.zenodo,cern,"Biodiversity,Taxonomy","[{'subject': 'Biodiversity'}, {'subject': 'Taxonomy'}]",,
+10.26302/sshade/experiment_lb_20200201_001,NIR spectra of a series of opal (-A and -CT) in ambient conditions and at low temperature (~ -35°C) and/or low pressure (~ 8 mbar),SSHADE/GhoSST (OSUG Data Center),2021.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",NIR spectra of 4 opal-A and 13 opal-CT in ambient conditions and at low temperature (~ -90°C) and/or low pressure (~ 8 mbar),mds,True,findable,0.0,0.0,0.0,0.0,0.0,2021-09-07T06:39:19.000Z,2021-09-07T06:39:20.000Z,inist.sshade,mgeg,"natural terrestrial,tektosilicate,opal,laboratory measurement,transmission,microscopy,MIR,Mid-Infrared,absorbance","[{'subject': 'natural terrestrial'}, {'subject': 'tektosilicate'}, {'subject': 'opal'}, {'subject': 'laboratory measurement'}, {'subject': 'transmission'}, {'subject': 'microscopy'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'absorbance'}]",['84 spectra'],['ASCII']
+10.15778/resif.yx2001,3F-Corinth Project temporary experiment (ENK6-CT-2000-00056),RESIF - Réseau Sismologique et géodésique Français,2017.0,en,Other,"Open Access,Creative Commons Attribution 4.0 International",Travel time tomography based on earthquakes,mds,True,findable,0.0,0.0,0.0,1.0,0.0,2018-04-19T11:40:11.000Z,2018-04-19T11:40:11.000Z,inist.resif,vcob,"Seismology,Tomography,Corinth Gulf,Greece","[{'subject': 'Seismology'}, {'subject': 'Tomography'}, {'subject': 'Corinth Gulf'}, {'subject': 'Greece'}]",,
+10.26302/sshade/experiment_lb_20180503_001,"Vis-NIR reflectance spectra (i=0°, e=30° and 60°) of 4 lunar soils (Appolo 15, 16, 17) under ambient conditions",SSHADE/GhoSST (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","Visible Near-IR reflectance spectra (i=0°, e=30° and e=60°) of 4 lunar soils: 15041 (Appolo 15), 65701 (Appolo 16), 74241 (Appolo 17) and 78221 (Appolo 17), under ambient conditions acquired with SHADOWS spectro-gonio radiometer @ IPAG",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2021-02-05T10:39:22.000Z,2021-02-05T10:39:23.000Z,inist.sshade,mgeg,"solid,planetary,tektosilicate,plagioclase,inosilicate,pyroxene,nesosilicate,olivine,oxide-hydroxide,ilmenite,laboratory measurement,bidirectional reflection,macroscopic,NIR,Near-Infrared,reflectance factor","[{'subject': 'solid'}, {'subject': 'planetary'}, {'subject': 'tektosilicate'}, {'subject': 'plagioclase'}, {'subject': 'inosilicate'}, {'subject': 'pyroxene'}, {'subject': 'nesosilicate'}, {'subject': 'olivine'}, {'subject': 'oxide-hydroxide'}, {'subject': 'ilmenite'}, {'subject': 'laboratory measurement'}, {'subject': 'bidirectional reflection'}, {'subject': 'macroscopic'}, {'subject': 'NIR'}, {'subject': 'Near-Infrared'}, {'subject': 'reflectance factor'}]",['8 spectra'],['ASCII']
+10.26302/sshade/bandlist_raman_aragonite,Raman bandlist of natural Aragonite,SSHADE/BANDLIST (OSUG Data Center),2021.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",FIR-MIR Raman bandlist of natural Aragonite at 295K and 80K,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-04-22T06:33:40.000Z,2023-04-22T06:33:40.000Z,inist.sshade,mgeg,"Aragonite,Calcium cation,Carbonate anion,Calcium(2+) cation,14127-61-8,Ca2+,(CO3)2-,CaCO3,Aragonite,non-silicate mineral,carbonate,carbonates, nitrates, borates,anhydrous carbonates,Aragonite group (Orthorhombic: Pmcn),14.01.03.01,05.AB.15,Raman scattering,MIR,FIR,band frequency,band width,band intensity,transition and vibration modes","[{'subject': 'Aragonite', 'subjectScheme': 'name'}, {'subject': 'Calcium cation', 'subjectScheme': 'name'}, {'subject': 'Carbonate anion', 'subjectScheme': 'name'}, {'subject': 'Calcium(2+) cation', 'subjectScheme': 'IUPAC name'}, {'subject': '14127-61-8', 'subjectScheme': 'CAS number'}, {'subject': 'Ca2+', 'subjectScheme': 'formula'}, {'subject': '(CO3)2-', 'subjectScheme': 'formula'}, {'subject': 'CaCO3', 'subjectScheme': 'formula'}, {'subject': 'Aragonite', 'subjectScheme': 'IMA name'}, {'subject': 'non-silicate mineral', 'subjectScheme': 'mineral class'}, {'subject': 'carbonate', 'subjectScheme': 'compound type'}, {'subject': 'carbonates, nitrates, borates', 'subjectScheme': 'Dana class'}, {'subject': 'anhydrous carbonates', 'subjectScheme': 'Dana class'}, {'subject': 'Aragonite group (Orthorhombic: Pmcn)', 'subjectScheme': 'Dana group'}, {'subject': '14.01.03.01', 'subjectScheme': 'Dana code'}, {'subject': '05.AB.15', 'subjectScheme': 'Strunz code'}, {'subject': 'Raman scattering', 'subjectScheme': 'variables'}, {'subject': 'MIR', 'subjectScheme': 'variables'}, {'subject': 'FIR', 'subjectScheme': 'variables'}, {'subject': 'band frequency', 'subjectScheme': 'variables'}, {'subject': 'band width', 'subjectScheme': 'variables'}, {'subject': 'band intensity', 'subjectScheme': 'variables'}, {'subject': 'transition and vibration modes', 'subjectScheme': 'variables'}]",,['ASCII']
+10.26302/sshade/experiment_op_20201203_001,W L3 edge XAS transmission of W metallic foil (5µm) at 300K,SSHADE/FAME (OSUG Data Center),2020.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2020-12-14T09:11:55.000Z,2020-12-14T09:11:56.000Z,inist.sshade,mgeg,"commercial,metal,metallic W,laboratory measurement,transmission,None,hard X,hard X-rays","[{'subject': 'commercial'}, {'subject': 'metal'}, {'subject': 'metallic W'}, {'subject': 'laboratory measurement'}, {'subject': 'transmission'}, {'subject': 'None'}, {'subject': 'hard X'}, {'subject': 'hard X-rays'}]",['1 spectrum'],['ASCII']
+10.26302/sshade/experiment_cc_20180724_01,VNIR reflectance spectra of Thermonatrite with 3 different grain sizes and at variable temperature (93-279 K),SSHADE/REFL_SLAB+CSS (OSUG Data Center),2019.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","Vis-NIR (0.5-4 µm) reflectance spectra of Thermonatrite with three different grain sizes (36-50, 75-100 and 125-150 µm) acquired at 11 temperatures between 93K and 279K",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2019-12-19T19:02:37.000Z,2019-12-19T19:02:38.000Z,inist.sshade,mgeg,"solid,commercial,carbonate,Thermonatrite,laboratory measurement,bidirectional reflection,macroscopic,Vis,Visible,NIR,Near-Infrared,reflectance factor","[{'subject': 'solid'}, {'subject': 'commercial'}, {'subject': 'carbonate'}, {'subject': 'Thermonatrite'}, {'subject': 'laboratory measurement'}, {'subject': 'bidirectional reflection'}, {'subject': 'macroscopic'}, {'subject': 'Vis'}, {'subject': 'Visible'}, {'subject': 'NIR'}, {'subject': 'Near-Infrared'}, {'subject': 'reflectance factor'}]",['35 spectra'],['ASCII']
+10.26302/sshade/experiment_cp_20180418_001,"Co K edge, Fe K edge and Pt L3 edge XAS fluorescence of CoFePt nanocomposite films",SSHADE/FAME (OSUG Data Center),2021.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","Varying composition, absorption edge and incidence angle",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2021-02-22T07:43:09.000Z,2021-02-22T07:43:11.000Z,inist.sshade,mgeg,"commercial,physically adsorbed phase,Pt,Fe,Co,laboratory measurement,fluorescence emission,None,hard X,hard X-rays","[{'subject': 'commercial'}, {'subject': 'physically adsorbed phase'}, {'subject': 'Pt'}, {'subject': 'Fe'}, {'subject': 'Co'}, {'subject': 'laboratory measurement'}, {'subject': 'fluorescence emission'}, {'subject': 'None'}, {'subject': 'hard X'}, {'subject': 'hard X-rays'}]",['17 spectra'],['ASCII']
+10.26302/sshade/experiment_ml_20171221_001,Zr K edge XAS fluorescence of haplogranite Zr F glass at ambient conditions,SSHADE/FAME (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2019-12-05T09:44:49.000Z,2019-12-05T09:44:50.000Z,inist.sshade,mgeg,"laboratory,silicate,Haplogranite Zr F glass,laboratory measurement,fluorescence emission,None,hard X","[{'subject': 'laboratory'}, {'subject': 'silicate'}, {'subject': 'Haplogranite Zr F glass'}, {'subject': 'laboratory measurement'}, {'subject': 'fluorescence emission'}, {'subject': 'None'}, {'subject': 'hard X'}]",['1 spectrum'],['ASCII']
+10.26302/sshade/bandlist_raman_hcn_hcn-ii,Raman band list of HCN in natural solid HCN (phase II),SSHADE/BANDLIST (OSUG Data Center),2021.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",MIR-FIR Raman band list of HCN in natural solid HCN (phase II) at 35 and 95 K,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-04-21T07:14:11.000Z,2023-04-21T07:14:12.000Z,inist.sshade,mgeg,"natural HCN - phase II,Hydrogen cyanide,Hydrogen cyanide phase II,HCN Phase II,Hydrogen cyanide,74-90-8,HCN,hydrogen bonded molecular solid,molecular solids with hydrogen bonded molecules,organic molecular solid,Raman scattering,FIR,MIR,band frequency,band width,band intensity,transition and vibration modes","[{'subject': 'natural HCN - phase II', 'subjectScheme': 'name'}, {'subject': 'Hydrogen cyanide', 'subjectScheme': 'name'}, {'subject': 'Hydrogen cyanide phase II', 'subjectScheme': 'name'}, {'subject': 'HCN Phase II', 'subjectScheme': 'name'}, {'subject': 'Hydrogen cyanide', 'subjectScheme': 'IUPAC name'}, {'subject': '74-90-8', 'subjectScheme': 'CAS number'}, {'subject': 'HCN', 'subjectScheme': 'formula'}, {'subject': 'hydrogen bonded molecular solid', 'subjectScheme': 'class'}, {'subject': 'molecular solids with hydrogen bonded molecules', 'subjectScheme': 'class'}, {'subject': 'organic molecular solid', 'subjectScheme': 'compound type'}, {'subject': 'Raman scattering', 'subjectScheme': 'var'}, {'subject': 'FIR', 'subjectScheme': 'var'}, {'subject': 'MIR', 'subjectScheme': 'var'}, {'subject': 'band frequency', 'subjectScheme': 'var'}, {'subject': 'band width', 'subjectScheme': 'var'}, {'subject': 'band intensity', 'subjectScheme': 'var'}, {'subject': 'transition and vibration modes', 'subjectScheme': 'var'}]",,['ASCII']
+10.26302/sshade/experiment_dt_20180117_004,Mo K edge XAS transmission of Mo metallic foil reference at ambient conditions,SSHADE/FAME (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2019-11-16T07:52:21.000Z,2019-11-16T07:52:22.000Z,inist.sshade,mgeg,"commercial,elemental solid,metallic Mo,laboratory measurement,transmission,None,hard X,hard X-rays","[{'subject': 'commercial'}, {'subject': 'elemental solid'}, {'subject': 'metallic Mo'}, {'subject': 'laboratory measurement'}, {'subject': 'transmission'}, {'subject': 'None'}, {'subject': 'hard X'}, {'subject': 'hard X-rays'}]",['1 spectrum'],['ASCII']
+10.26302/sshade/experiment_rb_20130101_001,"Ion irradiation ($He^+$, $Ar^+$) of an Allende meteorite pellet probed by Raman spectroscopy",SSHADE/DAYSY (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","Raman spectra of pellet n°1 and n°2 of the Allende meteorite, with different irradiation spots on the surface. Raman micro-spectroscopy was performed at the SMIS beamline at SOLEIL using a DXR Raman micro-spectrometer from Thermo Fisher with a 532 nm exciting laser radiation, and a power on the sample lower than 0.3 mW, producing power densities lower than 300 W/mm2.",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2022-05-27T17:02:42.000Z,2022-05-27T17:02:42.000Z,inist.sshade,mgeg,"extraterrestrial,carbonaceous chondrite,CV,complex organic-mineral mix,matrix Allende,complex mineral mix,chondrules Allende,CAIs Allende,laboratory measurement,Raman scattering,micro-imaging,MIR,Mid-Infrared,FIR,Far-Infrared,Raman scattering intensity","[{'subject': 'extraterrestrial'}, {'subject': 'carbonaceous chondrite'}, {'subject': 'CV'}, {'subject': 'complex organic-mineral mix'}, {'subject': 'matrix Allende'}, {'subject': 'complex mineral mix'}, {'subject': 'chondrules Allende'}, {'subject': 'CAIs Allende'}, {'subject': 'laboratory measurement'}, {'subject': 'Raman scattering'}, {'subject': 'micro-imaging'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'FIR'}, {'subject': 'Far-Infrared'}, {'subject': 'Raman scattering intensity'}]",['9 spectra'],['ASCII']
+10.15778/resif.yr2013,Seismic network YR:DOMERAPI temporary experiment (RESIF-SISMOB,RESIF - Réseau Sismologique et géodésique Français,2018.0,en,Dataset,"Open Access,Creative Commons Attribution 4.0 International","A network of 46 3-components seismometers has been deployed for 18 months (October 2013-April 2015) over the Merapi-Merbabu complex and surrounding region in order to record the local and regional seismic activity. Some stations were moved during the experiment. The dataset includes a total of 53 recording locations. Most of the stations cover the Merapi-Merbabu complex, which represents an area of approximately 50x50 km",mds,True,findable,0.0,0.0,0.0,1.0,0.0,2018-06-05T14:58:42.000Z,2018-06-05T14:58:42.000Z,inist.resif,vcob,"Volcano,Merapi,Java","[{'subject': 'Volcano'}, {'subject': 'Merapi'}, {'subject': 'Java'}]","['53 stations during 3 years, 1.1 Tb']","['Miniseed data', 'stationXML metadata']"
+10.26302/sshade/experiment_cb_20190408_001,Se K edge XAS HERFD of selenium with various oxidation states at 10K,SSHADE/FAME (OSUG Data Center),2019.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2019-11-15T20:23:12.000Z,2019-11-15T20:23:13.000Z,inist.sshade,mgeg,"solid,commercial,non-oxide ceramic,BN powder,anhydrous salt,Sodium selenate (SeVI),Sodium selenite (SeIV),Sodium selenide (SeII),organic molecular solid,Se-methionine,Se-cysteine,Se-cystine,Se-cystamine dihydrochloride,Se-urea,elemental solid,Se0 red,molecular solid solution,Frozen solution of Sodium selenate (SeVI),Frozen solution of Sodium selenite (SeIV),Frozen solution of Sodium selenide (SeII),Frozen solution of Se-glutathione peroxidase,Frozen solution of Se-methionine,Frozen solution of Se-diglutathione,Frozen solution of Se-cystine,laboratory measurement,fluorescence emission,None,hard X,hard X-rays","[{'subject': 'solid'}, {'subject': 'commercial'}, {'subject': 'non-oxide ceramic'}, {'subject': 'BN powder'}, {'subject': 'anhydrous salt'}, {'subject': 'Sodium selenate (SeVI)'}, {'subject': 'Sodium selenite (SeIV)'}, {'subject': 'Sodium selenide (SeII)'}, {'subject': 'organic molecular solid'}, {'subject': 'Se-methionine'}, {'subject': 'Se-cysteine'}, {'subject': 'Se-cystine'}, {'subject': 'Se-cystamine dihydrochloride'}, {'subject': 'Se-urea'}, {'subject': 'elemental solid'}, {'subject': 'Se0 red'}, {'subject': 'molecular solid solution'}, {'subject': 'Frozen solution of Sodium selenate (SeVI)'}, {'subject': 'Frozen solution of Sodium selenite (SeIV)'}, {'subject': 'Frozen solution of Sodium selenide (SeII)'}, {'subject': 'Frozen solution of Se-glutathione peroxidase'}, {'subject': 'Frozen solution of Se-methionine'}, {'subject': 'Frozen solution of Se-diglutathione'}, {'subject': 'Frozen solution of Se-cystine'}, {'subject': 'laboratory measurement'}, {'subject': 'fluorescence emission'}, {'subject': 'None'}, {'subject': 'hard X'}, {'subject': 'hard X-rays'}]",['16 spectra'],['ASCII']
+10.26302/sshade/experiment_lm_20221111_0001,"Vis-NIR reflectance spectra of pellets of olivine (0.1-1 mm), magnesite (inf. 0.1 mm) and antigorite (inf. 0.1 mm) mixtures",SSHADE/ROMA (OSUG Data Center),2022.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","Vis-NIR reflectance spectra (i=0°, e=30°, az=0°) of olivine, magnesite and antigorite mixtures (pellets), in various fractions.",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2022-11-11T22:43:34.000Z,2022-11-11T22:43:34.000Z,inist.sshade,mgeg,"mineral,natural terrestrial,phyllosilicate,antigorite,carbonate,magnesite,nesosilicate,olivine,laboratory measurement,bidirectional reflection,macroscopic,Vis,Visible,NIR,Near-Infrared,reflectance factor","[{'subject': 'mineral'}, {'subject': 'natural terrestrial'}, {'subject': 'phyllosilicate'}, {'subject': 'antigorite'}, {'subject': 'carbonate'}, {'subject': 'magnesite'}, {'subject': 'nesosilicate'}, {'subject': 'olivine'}, {'subject': 'laboratory measurement'}, {'subject': 'bidirectional reflection'}, {'subject': 'macroscopic'}, {'subject': 'Vis'}, {'subject': 'Visible'}, {'subject': 'NIR'}, {'subject': 'Near-Infrared'}, {'subject': 'reflectance factor'}]",['45 spectra'],['ASCII']
+10.26302/sshade/bandlist_abs_ch3cn_beta-ch3cn,Absorption band list of CH3CN in natural solid CH3CN (phase beta),SSHADE/BANDLIST (OSUG Data Center),2021.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",FIR-MIR absorption band list of $CH_3CN$ in natural solid $CH_3CN$ (phase beta) at 35 and 95 K,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-04-21T07:03:19.000Z,2023-04-21T07:03:20.000Z,inist.sshade,mgeg,"natural CH3CN - phase beta,Acetonitrile,beta-Acetonitrile,beta-acetonitrile (phase I),Acetonitrile,75-05-8,CH3CN,polar molecular solid,molecular solids with polar molecules,nitrile,absorption,FIR,MIR,NIR,band frequency,band width,band intensity,transition and vibration modes","[{'subject': 'natural CH3CN - phase beta', 'subjectScheme': 'name'}, {'subject': 'Acetonitrile', 'subjectScheme': 'name'}, {'subject': 'beta-Acetonitrile', 'subjectScheme': 'name'}, {'subject': 'beta-acetonitrile (phase I)', 'subjectScheme': 'name'}, {'subject': 'Acetonitrile', 'subjectScheme': 'IUPAC name'}, {'subject': '75-05-8', 'subjectScheme': 'CAS number'}, {'subject': 'CH3CN', 'subjectScheme': 'formula'}, {'subject': 'polar molecular solid', 'subjectScheme': 'class'}, {'subject': 'molecular solids with polar molecules', 'subjectScheme': 'class'}, {'subject': 'nitrile', 'subjectScheme': 'compound type'}, {'subject': 'absorption', 'subjectScheme': 'var'}, {'subject': 'FIR', 'subjectScheme': 'var'}, {'subject': 'MIR', 'subjectScheme': 'var'}, {'subject': 'NIR', 'subjectScheme': 'var'}, {'subject': 'band frequency', 'subjectScheme': 'var'}, {'subject': 'band width', 'subjectScheme': 'var'}, {'subject': 'band intensity', 'subjectScheme': 'var'}, {'subject': 'transition and vibration modes', 'subjectScheme': 'var'}]",,['ASCII']
+10.15778/resif.zr2020,"SEIS-ADELICE temporary experiment measuring the cryo-seismicity of the Astrolabe glacier in Terre Adelie, Antarctica (RESIF-SISMOB)",RESIF - Réseau Sismologique et géodésique Français,2023.0,,Dataset,,"To analyze the dynamics of Antarctica coastal glaciers and their interaction with the ocean, SEIS-ADELICE aims at measuring the cryo-seismicity of the Astrolabe glacier (Terre Adélie, Antarctica) from land and ocean bottom seismic observations. The first instrumental deployments occurred in January and February 2022. They consisted in a network of 6 broad-band (BB) stations from the French INSU-SISMOB pool deployed on the grounding line of the Astrolabe glacier, together with 4 OBS deployed at sea few km off the floating tongue of the glacier. These stations were complemented by semi-permanent BB seismological stations deployed on stable ice around the glacier for long term (several years) recording of the ice and of the glacier cryogenic activity.",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-01-30T18:27:13.000Z,2023-01-30T18:28:20.000Z,inist.resif,vcob,"Cryoseismology,Astrolabe Glacier,East Antarctica,grounding line,Dumont d'Urville base,ice-ocean interaction,icequakes,tremors,glacial earthquakes,icebergs,calving,brittle deformation,basal sliding,anisotropy","[{'subject': 'Cryoseismology'}, {'subject': 'Astrolabe Glacier'}, {'subject': 'East Antarctica'}, {'subject': 'grounding line'}, {'subject': ""Dumont d'Urville base""}, {'subject': 'ice-ocean interaction'}, {'subject': 'icequakes'}, {'subject': 'tremors'}, {'subject': 'glacial earthquakes'}, {'subject': 'icebergs'}, {'subject': 'calving'}, {'subject': 'brittle deformation'}, {'subject': 'basal sliding'}, {'subject': 'anisotropy'}]","['10 stations, 9Go (miniseed format)']","['Miniseed data', 'stationXML metadata']"
+10.26302/sshade/experiment_zed_20230705_01,NIR reflectance spectra of Mercury minerals analogs cooled up to 148K,SSHADE/DAYSY (OSUG Data Center),2023.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",NIR reflectance spectra of Mercury minerals analogs (anorthite 80 and synthetic volcanic glasses) cooled by 50K step up to 148 K.,mds,True,findable,0.0,0.0,2.0,0.0,0.0,2023-07-10T14:20:24.000Z,2023-07-10T14:20:24.000Z,inist.sshade,mgeg,"laboratory measurement,confocal reflection,micro-imaging,NIR,Near-Infrared,reflectance factor,Bytownite,mineral,natural terrestrial,silicate","[{'subject': 'laboratory measurement', 'subjectScheme': 'main'}, {'subject': 'confocal reflection', 'subjectScheme': 'main'}, {'subject': 'micro-imaging', 'subjectScheme': 'main'}, {'subject': 'NIR', 'subjectScheme': 'variables'}, {'subject': 'Near-Infrared', 'subjectScheme': 'variables'}, {'subject': 'reflectance factor', 'subjectScheme': 'variables'}, {'subject': 'Bytownite', 'subjectScheme': 'name'}, {'subject': 'mineral', 'subjectScheme': 'family'}, {'subject': 'natural terrestrial', 'subjectScheme': 'origin'}, {'subject': 'silicate', 'subjectScheme': 'compound type'}]",['16 spectra'],['ASCII']
+10.26302/sshade/experiment_bs_20160831_000,"Vis-NIR spectral bidirectional reflection distribution fonction (SBRDF) of sintered snow (Arselle) and slab ice (3 thicknesses: 1.42, 7.45 and 12.5 mm) on snow at -10°C",SSHADE/GhoSST (OSUG Data Center),2020.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","Vis-NIR BRDF spectra of sintered snow (from Arselle) [i=0, 20, 30, 40, 50, 60, 65°; e=0, 20, 40, 50, 65°; az=0, 45, 90, 140, 160, 180°], of snow with a thin top slab of ice (3 thicknesses: 1.42, 7.45, 12.5mm) [i=40, 50, 60, 70°; e=0, 10, 20°; az=0, 45, 90, 140, 160, 180°], and of the specular peak of the 12.5mm slab [i=50, e=50°$\pm$5°; i=65°, e=65°$\pm$5°; az=170-180°] - T = -10°C",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2020-03-17T22:00:36.000Z,2020-03-17T22:00:38.000Z,inist.sshade,mgeg,"natural terrestrial,inorganic molecular solid,natural H2O ice,laboratory,laboratory measurement,bidirectional reflection,macroscopic,Vis,Visible,NIR,Near-Infrared,reflectance factor","[{'subject': 'natural terrestrial'}, {'subject': 'inorganic molecular solid'}, {'subject': 'natural H2O ice'}, {'subject': 'laboratory'}, {'subject': 'laboratory measurement'}, {'subject': 'bidirectional reflection'}, {'subject': 'macroscopic'}, {'subject': 'Vis'}, {'subject': 'Visible'}, {'subject': 'NIR'}, {'subject': 'Near-Infrared'}, {'subject': 'reflectance factor'}]",['19 spectra'],['ASCII']
+10.5281/zenodo.10485577,"Fig. 2 in The chloroplast membrane associated ceQORH putative quinone oxidoreductase reduces long-chain, stress-related oxidized lipids",Zenodo,2016.0,,Image,License Not Specified,"Fig. 2. ceQORH activity in the presence C9 and C10 Oi,β-unsaturated carbonyls. (A) ceQORH activity was measured as a function of trans-2-nonenal concentration. k = 0.04 ± 0.005 s –1, K = 66 ± 25 µM. (B) ceQORH activity was measured as a function of trans-3-decen-2-one concentration. The apparent affinity was too low to cat M determine KM and kcat parameters accurately. (C) ceQORH activity was measured as a function of 4-hydroxynonenal concentration. The apparent affinity for this molecule was very low and neither k nor K could be determined. (D) ceQORH activity was measured as a function of 4-oxo-nonenal concentration. k = 14 ± 1 s –1, K = 190 ± 50 µM.",api,True,findable,0.0,0.0,0.0,0.0,0.0,2024-01-11T04:59:34.000Z,2024-01-11T04:59:34.000Z,cern.zenodo,cern,"Biodiversity,Taxonomy","[{'subject': 'Biodiversity'}, {'subject': 'Taxonomy'}]",,
+10.26302/sshade/experiment_bs_20201114_012,"Near-infrared reflectance spectra at low temperature (300-90K) of Salammoniac and delta-Ammonium chloride (phase IV) [NH4Cl] powders with three grain size ranges (32-80, 80-125 and 125-150µm)",SSHADE/CSS (OSUG Data Center),2022.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","Near-infrared reflectance spectra at low temperature of Salammoniac (beta-Ammonium chloride, phase II) (290-243K) and delta-Ammonium chloride (phase IV) (242-90K) powder [NH4Cl] with 32-80 µm grain size and Salammoniac powder at room temperature with 80-125µm and 125-150µm grain sizes",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2022-04-23T08:19:39.000Z,2022-04-23T08:19:39.000Z,inist.sshade,mgeg,"natural terrestrial,halide,Salammoniac,laboratory,chloride,delta-Ammonium chloride (phase IV),Sal ammoniac,laboratory measurement,bidirectional reflection,macroscopic,NIR,Near-Infrared,reflectance factor","[{'subject': 'natural terrestrial'}, {'subject': 'halide'}, {'subject': 'Salammoniac'}, {'subject': 'laboratory'}, {'subject': 'chloride'}, {'subject': 'delta-Ammonium chloride (phase IV)'}, {'subject': 'Sal ammoniac'}, {'subject': 'laboratory measurement'}, {'subject': 'bidirectional reflection'}, {'subject': 'macroscopic'}, {'subject': 'NIR'}, {'subject': 'Near-Infrared'}, {'subject': 'reflectance factor'}]",['31 spectra'],['ASCII']
+10.26302/sshade/bandlist_raman_n2_beta-n2,Raman band list of N2 in natural solid N2 (phase beta),SSHADE/BANDLIST (OSUG Data Center),2023.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",MIR Raman band list of the isotopes of $N_2$ in natural solid $\beta-N2$,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-05-08T15:31:59.000Z,2023-05-08T15:31:59.000Z,inist.sshade,mgeg,"natural N2 - phase beta,Nitrogen,Solid beta Nitrogen,$\beta$-phase,Dinitrogen,7727-37-9,N2,non polar molecular solid,molecular solids with apolar molecules,inorganic molecular solid,Raman scattering,MIR,band frequency,band width,band intensity,transition and vibration modes","[{'subject': 'natural N2 - phase beta', 'subjectScheme': 'name'}, {'subject': 'Nitrogen', 'subjectScheme': 'name'}, {'subject': 'Solid beta Nitrogen', 'subjectScheme': 'name'}, {'subject': '$\\beta$-phase', 'subjectScheme': 'name'}, {'subject': 'Dinitrogen', 'subjectScheme': 'IUPAC name'}, {'subject': '7727-37-9', 'subjectScheme': 'CAS number'}, {'subject': 'N2', 'subjectScheme': 'formula'}, {'subject': 'non polar molecular solid', 'subjectScheme': 'class'}, {'subject': 'molecular solids with apolar molecules', 'subjectScheme': 'class'}, {'subject': 'inorganic molecular solid', 'subjectScheme': 'compound type'}, {'subject': 'Raman scattering', 'subjectScheme': 'var'}, {'subject': 'MIR', 'subjectScheme': 'var'}, {'subject': 'band frequency', 'subjectScheme': 'var'}, {'subject': 'band width', 'subjectScheme': 'var'}, {'subject': 'band intensity', 'subjectScheme': 'var'}, {'subject': 'transition and vibration modes', 'subjectScheme': 'var'}]",,['ASCII']
+10.15778/resif.xy2007,Seismic network XY:SIMBAAD temporary experiment - Backbone of broadband stations,RESIF - Réseau Sismologique et géodésique Français,2013.0,en,Other,"Open Access,Creative Commons Attribution 4.0 International","Temporary seismic array of broadband stations in Turkey, Greece and Bulgaria complementing the permanent arrays of Greece and Turkey to an average interstation spacing of 80-100 km. Goal: imaging of the crust and upper mantle using earthquake and noise records. Sensors: Streckheisen STS2 and Güralp CMG3ESP (90s). Digitizers: Agecodagis Minititan",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2015-12-02T12:45:43.000Z,2015-12-02T12:45:43.000Z,inist.resif,vcob,"Greece and Western Turkey,Aegean and Anatolian regions,Structure of the crust and upper mantle,Seismic imaging","[{'subject': 'Greece and Western Turkey'}, {'subject': 'Aegean and Anatolian regions'}, {'subject': 'Structure of the crust and upper mantle'}, {'subject': 'Seismic imaging'}]",,
+10.26302/sshade/experiment_soc_20201214_001,Pd K edge XAS transmission of Pd metallic foil at 300K,SSHADE/FAME (OSUG Data Center),2020.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2020-12-14T13:08:55.000Z,2020-12-14T13:08:56.000Z,inist.sshade,mgeg,"commercial,metal,metallic Pd,laboratory measurement,transmission,None,hard X,hard X-rays","[{'subject': 'commercial'}, {'subject': 'metal'}, {'subject': 'metallic Pd'}, {'subject': 'laboratory measurement'}, {'subject': 'transmission'}, {'subject': 'None'}, {'subject': 'hard X'}, {'subject': 'hard X-rays'}]",['1 spectrum'],['ASCII']
+10.26302/sshade/experiment_lb_20170721_001,"Mid-IR absorbance spectra of bulk CM chondrites in KBr pellets at ambient temperature, 150°C and 300°C",SSHADE/GhoSST (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","Mid-IR absorbance spectra of bulk CM chondrites at 3 different temperatures: ambient temperature, 150°C and 300°C",mds,True,findable,0.0,0.0,0.0,1.0,0.0,2020-02-26T17:32:42.000Z,2020-02-26T17:32:43.000Z,inist.sshade,mgeg,"extraterrestrial,complex organic-mineral mix,matrix Boriskino,complex mineral mix,chondrules Boriskino,CAIs Boriskino,physically adsorbed phase,adsorbed water on Boriskino bulk,commercial,bromide,KBr,adsorbed water on KBr (Beck14),matrix Boriskino heated at 150C,matrix Boriskino heated at 300C,matrix LEW85311,chondrules LEW85311,CAIs LEW85311,adsorbed water on LEW85311 bulk,matrix LEW85311 heated at 150C,matrix LEW85311 heated at 300C,matrix QUE97990,chondrules QUE97990,CAIs QUE97990,adsorbed water on QUE97990 bulk,matrix QUE97990 heated at 150C,matrix QUE97990 heated at 300C,matrix Murchison,chondrules Murchison,CAIs Murchison,adsorbed water on MURCHISON bulk,matrix MURCHISON heated at 150C,matrix MURCHISON heated at 300C,matrix MCY05230,chondrules MCY05230,CAIs MCY05230,adsorbed water on MCY05230 bulk,matrix MCY05230 heated at 150C,matrix MCY05230 heated at 300C,matrix LON94101,chondrules LON94101,CAIs LON94101,adsorbed water on LON94101 bulk,matrix LON94101 heated at 150C,matrix LON94101 heated at 300C,matrix QUE99355,chondrules QUE99355,CAIs QUE99355,adsorbed water on QUE99355 bulk,matrix QUE99355 heated at 150C,matrix QUE99355 heated at 300C,matrix DOM03183,chondrules DOM03183,CAIs DOM03183,adsorbed water on DOM03183 bulk,matrix DOM03183 heated at 150C,matrix DOM03183 heated at 300C,matrix LEW87022,chondrules LEW87022,CAIs LEW87022,adsorbed water on LEW87022 bulk,matrix LEW87022 heated at 150C,matrix LEW87022 heated at 300C,matrix DOM08003,chondrules DOM08003,CAIs DOM08003,adsorbed water on DOM08003 bulk,matrix DOM08003 heated at 150C,matrix DOM08003 heated at 300C,matrix Nogoya,chondrules Nogoya,CAIs Nogoya,adsorbed water on NOGOYA bulk,matrix NOGOYA heated at 150C,matrix NOGOYA heated at 300C,matrix ALH84044,chondrules ALH84044,CAIs ALH84044,adsorbed water on ALH84044 bulk,matrix ALH84044 heated at 150C,matrix ALH84044 heated at 300C,matrix ALH83100,chondrules ALH83100,CAIs ALH83100,adsorbed water on ALH83100 bulk,matrix ALH83100 heated at 150C,matrix ALH83100 heated at 300C,laboratory measurement,transmission,macroscopic,MIR,Mid-Infrared,absorbance","[{'subject': 'extraterrestrial'}, {'subject': 'complex organic-mineral mix'}, {'subject': 'matrix Boriskino'}, {'subject': 'complex mineral mix'}, {'subject': 'chondrules Boriskino'}, {'subject': 'CAIs Boriskino'}, {'subject': 'physically adsorbed phase'}, {'subject': 'adsorbed water on Boriskino bulk'}, {'subject': 'commercial'}, {'subject': 'bromide'}, {'subject': 'KBr'}, {'subject': 'adsorbed water on KBr (Beck14)'}, {'subject': 'matrix Boriskino heated at 150C'}, {'subject': 'matrix Boriskino heated at 300C'}, {'subject': 'matrix LEW85311'}, {'subject': 'chondrules LEW85311'}, {'subject': 'CAIs LEW85311'}, {'subject': 'adsorbed water on LEW85311 bulk'}, {'subject': 'matrix LEW85311 heated at 150C'}, {'subject': 'matrix LEW85311 heated at 300C'}, {'subject': 'matrix QUE97990'}, {'subject': 'chondrules QUE97990'}, {'subject': 'CAIs QUE97990'}, {'subject': 'adsorbed water on QUE97990 bulk'}, {'subject': 'matrix QUE97990 heated at 150C'}, {'subject': 'matrix QUE97990 heated at 300C'}, {'subject': 'matrix Murchison'}, {'subject': 'chondrules Murchison'}, {'subject': 'CAIs Murchison'}, {'subject': 'adsorbed water on MURCHISON bulk'}, {'subject': 'matrix MURCHISON heated at 150C'}, {'subject': 'matrix MURCHISON heated at 300C'}, {'subject': 'matrix MCY05230'}, {'subject': 'chondrules MCY05230'}, {'subject': 'CAIs MCY05230'}, {'subject': 'adsorbed water on MCY05230 bulk'}, {'subject': 'matrix MCY05230 heated at 150C'}, {'subject': 'matrix MCY05230 heated at 300C'}, {'subject': 'matrix LON94101'}, {'subject': 'chondrules LON94101'}, {'subject': 'CAIs LON94101'}, {'subject': 'adsorbed water on LON94101 bulk'}, {'subject': 'matrix LON94101 heated at 150C'}, {'subject': 'matrix LON94101 heated at 300C'}, {'subject': 'matrix QUE99355'}, {'subject': 'chondrules QUE99355'}, {'subject': 'CAIs QUE99355'}, {'subject': 'adsorbed water on QUE99355 bulk'}, {'subject': 'matrix QUE99355 heated at 150C'}, {'subject': 'matrix QUE99355 heated at 300C'}, {'subject': 'matrix DOM03183'}, {'subject': 'chondrules DOM03183'}, {'subject': 'CAIs DOM03183'}, {'subject': 'adsorbed water on DOM03183 bulk'}, {'subject': 'matrix DOM03183 heated at 150C'}, {'subject': 'matrix DOM03183 heated at 300C'}, {'subject': 'matrix LEW87022'}, {'subject': 'chondrules LEW87022'}, {'subject': 'CAIs LEW87022'}, {'subject': 'adsorbed water on LEW87022 bulk'}, {'subject': 'matrix LEW87022 heated at 150C'}, {'subject': 'matrix LEW87022 heated at 300C'}, {'subject': 'matrix DOM08003'}, {'subject': 'chondrules DOM08003'}, {'subject': 'CAIs DOM08003'}, {'subject': 'adsorbed water on DOM08003 bulk'}, {'subject': 'matrix DOM08003 heated at 150C'}, {'subject': 'matrix DOM08003 heated at 300C'}, {'subject': 'matrix Nogoya'}, {'subject': 'chondrules Nogoya'}, {'subject': 'CAIs Nogoya'}, {'subject': 'adsorbed water on NOGOYA bulk'}, {'subject': 'matrix NOGOYA heated at 150C'}, {'subject': 'matrix NOGOYA heated at 300C'}, {'subject': 'matrix ALH84044'}, {'subject': 'chondrules ALH84044'}, {'subject': 'CAIs ALH84044'}, {'subject': 'adsorbed water on ALH84044 bulk'}, {'subject': 'matrix ALH84044 heated at 150C'}, {'subject': 'matrix ALH84044 heated at 300C'}, {'subject': 'matrix ALH83100'}, {'subject': 'chondrules ALH83100'}, {'subject': 'CAIs ALH83100'}, {'subject': 'adsorbed water on ALH83100 bulk'}, {'subject': 'matrix ALH83100 heated at 150C'}, {'subject': 'matrix ALH83100 heated at 300C'}, {'subject': 'laboratory measurement'}, {'subject': 'transmission'}, {'subject': 'macroscopic'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'absorbance'}]",['39 spectra'],['ASCII']
+10.6084/m9.figshare.12926231,Additional file 1 of Expert consensus-based clinical practice guidelines management of intravascular catheters in the intensive care unit,figshare,2020.0,,Text,Creative Commons Attribution 4.0 International,Additional file 1. Pediatrics R1 Chlorhexidine-alcohol disinfection. Pediatrics R2 and R4 US and site of insertion. Pediatrics R3 radial vs. femoral artery access. Pediatrics R5 impregnated impregnated CVCs. Pediadrics R6 heparin bonded CVCs. Pediatrics R7 continuous quality improvement program. Pediatrics R8 CHG dressings CVCs and arterial catheters. Adults and pediatrics Prevention R 1-1 and 1-2 subclavian vs. Internal jugular vs. femoral. R 1-3 alc-CHG vs. alc-PVI. R 1-4 1 step vs. 4 steps desinfections. R 1-5 antiseptic and antibiotic impregnated catheters. R1-6 heparin bonded CVCs. R 1-7 CHG dressings vs. transparent dressings. R 1-8 dressing change frequencies. R 1-9 R1-10 R 1-11 R1-12 US and site of insertion. Surveillance R 2.1 R2.2 surveillance network. R 2-2 quality improvement program. R2-3 culture of catheters Catheter related infection R3-1 R3-4 blood culture. R3-2 R3-3a R3-3b persistent bacteraemia : R 3-5 R3-6 R3-7 R3-9 R3-15 Catheter removed. R3-8 R3-10 R3-12 R3-13 duration of antibiotics. R3-11 antifungal therapy R3-14 antibiotic therapy.,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2020-09-08T03:48:23.000Z,2020-09-08T03:48:24.000Z,figshare.ars,otjm,"Medicine,Cell Biology,Environmental Sciences not elsewhere classified,Biological Sciences not elsewhere classified,Marine Biology,Science Policy,Infectious Diseases,FOS: Health sciences","[{'subject': 'Medicine'}, {'subject': 'Cell Biology'}, {'subject': 'Environmental Sciences not elsewhere classified'}, {'subject': 'Biological Sciences not elsewhere classified'}, {'subject': 'Marine Biology'}, {'subject': 'Science Policy'}, {'subject': 'Infectious Diseases'}, {'subject': 'FOS: Health sciences', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}]",['427118 Bytes'],
+10.26302/sshade/experiment_gs_20170713_002,Ag K edge XAS transmission of AgCl,SSHADE/FAME (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2019-12-05T14:39:28.000Z,2019-12-05T14:39:55.000Z,inist.sshade,mgeg,"solid,commercial,non-oxide ceramic,BN powder,chloride,AgCl,laboratory measurement,transmission,None,hard X,hard X-rays","[{'subject': 'solid'}, {'subject': 'commercial'}, {'subject': 'non-oxide ceramic'}, {'subject': 'BN powder'}, {'subject': 'chloride'}, {'subject': 'AgCl'}, {'subject': 'laboratory measurement'}, {'subject': 'transmission'}, {'subject': 'None'}, {'subject': 'hard X'}, {'subject': 'hard X-rays'}]",['1 spectrum'],['ASCII']
+10.26302/sshade/experiment_dm_20141115_002,"NIR and MIR reflectance spectra of mixtures of UARK tholins with liquid and solid CH4, C2H6 and CH3CN at several temperatures",SSHADE/SOSYPOL (OSUG Data Center),2020.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","NIR and MIR reflectance spectra of synthesized UARK tholins (from 90% N2:10% CH4) pure and mixed with various liquids and solids (CH4, C2H6 and CH3CN) at varying temperature",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2020-02-13T12:08:53.000Z,2020-02-13T12:08:54.000Z,inist.sshade,mgeg,"carbonaceous,laboratory,complex macromolecular mixture,Tholins UARK 90N2 10CH4,commercial,liquid,Liquid C2H6,Liquid CH4,Liquid CH3CN,laboratory measurement,bidirectional reflection,macroscopic,NIR,Near-Infrared,MIR,Mid-Infrared,reflectance factor","[{'subject': 'carbonaceous'}, {'subject': 'laboratory'}, {'subject': 'complex macromolecular mixture'}, {'subject': 'Tholins UARK 90N2 10CH4'}, {'subject': 'commercial'}, {'subject': 'liquid'}, {'subject': 'Liquid C2H6'}, {'subject': 'Liquid CH4'}, {'subject': 'Liquid CH3CN'}, {'subject': 'laboratory measurement'}, {'subject': 'bidirectional reflection'}, {'subject': 'macroscopic'}, {'subject': 'NIR'}, {'subject': 'Near-Infrared'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'reflectance factor'}]",['29 spectra'],['ASCII']
+10.15778/resif.xz2020,"DEEP_TRIGGER temporary experiment in the subduction zone Peru/Chile, Chile (RESIF-SISMOB)",RESIF - Réseau Sismologique et géodésique Français,2020.0,,Dataset,,"Preparation of subduction Earthquakes : Slow, Deep, Large-scale trigger. DeepTrigger is a project funded by the European Research Council. The aim of the project is to study the preparation of subduction earthquakes in the Chile/Peru subduction area. The seismological network deployed in Chile (XZ network) is composed of 25 stations medium-band velocimeter (Guralp CMG40-60s and Nanometrics Trillium-Compact-PostHole-20s). Those 25 stations will be deployed during ~3 years in middle area of Chile (Network code XZ) from mid-2021 to mid-2024. The targeted area in North-Central Chile (27°S-30°S) is located just north of the 2015 Illapel rupture. It is a recognized ‘seismic gap’, where the last earthquakes of Mw8.5+ occurred in1819 and 1922, and where a future large event is to be expected. The area is characterized by an interseismic coupling that evolves from low in the south to high in the north (Métois et al., 2018), and where deep slow slip events have been recently discovered (Klein et al., 2018). This is therefore an excellent target to study the preparation of a future large earthquake, the lateral interactions between large seismic ruptures, and the link between slow slip and the seismic response to slow slip. The installed seismological network will provide key data to investigate these questions. Precise catalogues of seismicity will be generated, in which swarm, repeaters and clusters will be identified and analysed. LFEs and tremors will also be systematically scanned, catalogued and analysed.",fabrica,True,findable,0.0,0.0,0.0,0.0,0.0,2023-03-01T20:34:07.000Z,2023-03-01T20:35:02.000Z,inist.resif,vcob,"Seismology,Subduction,Earthquake,Chile,South America","[{'subject': 'Seismology'}, {'subject': 'Subduction'}, {'subject': 'Earthquake'}, {'subject': 'Chile'}, {'subject': 'South America'}]","['26 stations, 203Go (miniseed format)']","['Miniseed data', 'stationXML metadata']"
+10.5281/zenodo.10485581,"Fig. 5 in The chloroplast membrane associated ceQORH putative quinone oxidoreductase reduces long-chain, stress-related oxidized lipids",Zenodo,2016.0,,Image,License Not Specified,"Fig. 5. LC/MS analyses of the reaction catalyzed by ceQORH in the presence of trans- 1,3-diphenyl-2-propenone and NADPH. (A) HPLC chromatogram recorded at 250 and 312 nm of a 90 min reaction. (B) LC/MS chromatogram. (C) MS spectrum of the elution pick at 3.99 min. The peak with m/z = 233.09 corresponds to the sodium ion of trans-1,3-diphenyl-2-propanone (D) MS spectrum of trans-1,3-diphenyl-2- propenone (m/z = 230.97 corresponds to the sodium ion of trans-1,3-diphenyl-2- propenone).",api,True,findable,0.0,0.0,0.0,0.0,0.0,2024-01-11T04:59:41.000Z,2024-01-11T04:59:42.000Z,cern.zenodo,cern,"Biodiversity,Taxonomy","[{'subject': 'Biodiversity'}, {'subject': 'Taxonomy'}]",,
+10.26302/sshade/experiment_bs_20130103_003,NIR optical constant spectra of CH4 in solid solution in alpha and beta-N2 phases at 5 different temperatures (35K - 43K),SSHADE/GhoSST (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","NIR optical constant spectra of CH4 in solid solution in two N2 ice phases: Beta-N2 phases at 43, 41, 38 and 36.5K. Changed to alpha-N2 phase at 35K",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2021-05-02T05:52:15.000Z,2021-05-02T05:52:16.000Z,inist.sshade,mgeg,"laboratory,solid molecular mixture,CH4:N2 crystalline solid solution - beta phase,CH4:N2 crystalline solid solution - alpha phase,laboratory measurement,transmission,macroscopic,NIR,Near-Infrared,optical constants","[{'subject': 'laboratory'}, {'subject': 'solid molecular mixture'}, {'subject': 'CH4:N2 crystalline solid solution - beta phase'}, {'subject': 'CH4:N2 crystalline solid solution - alpha phase'}, {'subject': 'laboratory measurement'}, {'subject': 'transmission'}, {'subject': 'macroscopic'}, {'subject': 'NIR'}, {'subject': 'Near-Infrared'}, {'subject': 'optical constants'}]",['5 spectra'],['ASCII']
+10.6084/m9.figshare.22625608,"Additional file 1 of A multicentre, patient- and assessor-blinded, non-inferiority, randomised and controlled phase II trial to compare standard and torque teno virus-guided immunosuppression in kidney transplant recipients in the first year after transplantation: TTVguideIT",figshare,2023.0,,Text,Creative Commons Attribution 4.0 International,Additional file 1.,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-04-13T18:56:32.000Z,2023-04-13T18:56:32.000Z,figshare.ars,otjm,"Immunology,FOS: Clinical medicine","[{'subject': 'Immunology'}, {'subject': 'FOS: Clinical medicine', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}]",['1508179 Bytes'],
+10.26302/sshade/experiment_jc_20220615_001,Y K edge XAS transmission and XAS fluorescence of Yttrium components at 20K,SSHADE/FAME (OSUG Data Center),2023.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","Determination of the yttrium speciation variability in bauxite residues of various origin, age and storage conditions",mds,True,findable,0.0,0.0,2.0,1.0,0.0,2023-11-10T10:53:00.000Z,2023-11-10T10:53:01.000Z,inist.sshade,mgeg,"laboratory measurement,transmission,None,fluorescence emission,hard X,metallic Y,Polyvinylpyrrolidone,Y2O3,Y(OH)3,Y2(CO3)3,Low crystallized xenotime YPO4,Medium crystalized xenotime YPO4,High crystallized xenotime YPO4,Churchite YPO4,Montmorillonite,Y-adsorbed on montmorillonite,Calcite,Y dopant,Low crystalized hydroxyapatite,High crystalized hydroxyapatite,hematite,solid,commercial,laboratory,elemental solid,homopolymer,oxide,hydroxide,carbonate,phosphate,phyllosilicate,chemically adsorbed phase,other complex mix,oxide-hydroxide","[{'subject': 'laboratory measurement', 'subjectScheme': 'main'}, {'subject': 'transmission', 'subjectScheme': 'main'}, {'subject': 'None', 'subjectScheme': 'main'}, {'subject': 'fluorescence emission', 'subjectScheme': 'main'}, {'subject': 'hard X', 'subjectScheme': 'variables'}, {'subject': 'metallic Y', 'subjectScheme': 'name'}, {'subject': 'Polyvinylpyrrolidone', 'subjectScheme': 'name'}, {'subject': 'Y2O3', 'subjectScheme': 'name'}, {'subject': 'Y(OH)3', 'subjectScheme': 'name'}, {'subject': 'Y2(CO3)3', 'subjectScheme': 'name'}, {'subject': 'Low crystallized xenotime YPO4', 'subjectScheme': 'name'}, {'subject': 'Medium crystalized xenotime YPO4', 'subjectScheme': 'name'}, {'subject': 'High crystallized xenotime YPO4', 'subjectScheme': 'name'}, {'subject': 'Churchite YPO4', 'subjectScheme': 'name'}, {'subject': 'Montmorillonite', 'subjectScheme': 'name'}, {'subject': 'Y-adsorbed on montmorillonite', 'subjectScheme': 'name'}, {'subject': 'Calcite', 'subjectScheme': 'name'}, {'subject': 'Y dopant', 'subjectScheme': 'name'}, {'subject': 'Low crystalized hydroxyapatite', 'subjectScheme': 'name'}, {'subject': 'High crystalized hydroxyapatite', 'subjectScheme': 'name'}, {'subject': 'hematite', 'subjectScheme': 'name'}, {'subject': 'solid', 'subjectScheme': 'family'}, {'subject': 'commercial', 'subjectScheme': 'origin'}, {'subject': 'laboratory', 'subjectScheme': 'origin'}, {'subject': 'elemental solid', 'subjectScheme': 'compound type'}, {'subject': 'homopolymer', 'subjectScheme': 'compound type'}, {'subject': 'oxide', 'subjectScheme': 'compound type'}, {'subject': 'hydroxide', 'subjectScheme': 'compound type'}, {'subject': 'carbonate', 'subjectScheme': 'compound type'}, {'subject': 'phosphate', 'subjectScheme': 'compound type'}, {'subject': 'phyllosilicate', 'subjectScheme': 'compound type'}, {'subject': 'chemically adsorbed phase', 'subjectScheme': 'compound type'}, {'subject': 'other complex mix', 'subjectScheme': 'compound type'}, {'subject': 'oxide-hydroxide', 'subjectScheme': 'compound type'}]",['13 spectra'],['ASCII']
+10.15778/resif.rg,RESIF-RENAG French national Geodetic Network,RESIF - Réseau Sismologique et géodésique Français,2017.0,en,Other,,"The RENAG goals are to install and maintain over the long term a network of permanent GPS stations for scientific applications. RENAG acquires, stores, validates, distributes and analyzes data from 72 university stations. 18 French research teams are actively involved in the establishment of observing systems, data acquisition, in their scientific exploitation and dissemination, and their sustainability (BD RENAG). The network's objectives are to 1) quantify the slow tectonic deformation of France, to establish the link with the moderate seismicity and to constrain models of the current deformation, thus contributing to the assessment of seismic hazard on the national territory, 2) constrain sea level variations, by separating vertical land motion from climatic contributions in tide gauge records thanks to co-located GPS stations, 3) fill a persistent observational gap of tropospheric water vapor in meteorology for the analysis of heavy rain events, for assimilation of GPS data in operational forecast models and to provide stable measurements over long periods for climatology, and 4) characterize the transient deformations induced by loads (atmospheric, oceanic, hydrological).",,True,findable,0.0,0.0,0.0,2.0,0.0,2017-04-19T13:05:39.000Z,2017-04-19T13:05:39.000Z,inist.resif,vcob,"Geodesy,GNSS","[{'subject': 'Geodesy'}, {'subject': 'GNSS'}]",['Approximately 72 active stations; greater than 25 MB/day.'],['RINEX data']
+10.26302/sshade/experiment_ak_20141103_1,Mid-infrared attenuated total reflectance experiment with Na+ exchanged less 1 μm size fraction of montmorillonite (SCa-3) equilibrated with D2O vapor under variable relative humidity,SSHADE/LSD (OSUG Data Center),2019.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2022-11-04T08:11:52.000Z,2022-11-04T08:11:53.000Z,inist.sshade,mgeg,"natural terrestrial,phyllosilicate,Na-exchanged montmorillonite SCa-3 size-fraction &lt;1 µm,liquid,D2O 99.9 Sigma-Aldrich,laboratory measurement,ATReflection,macroscopic,MIR,Mid-Infrared,corrected ATR absorbance","[{'subject': 'natural terrestrial'}, {'subject': 'phyllosilicate'}, {'subject': 'Na-exchanged montmorillonite SCa-3 size-fraction &lt;1 µm'}, {'subject': 'liquid'}, {'subject': 'D2O 99.9 Sigma-Aldrich'}, {'subject': 'laboratory measurement'}, {'subject': 'ATReflection'}, {'subject': 'macroscopic'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'corrected ATR absorbance'}]",['2 spectra'],['ASCII']
+10.5281/zenodo.10548744,WRFChem MOSAiC run,Zenodo,2024.0,,Dataset,Creative Commons Attribution 4.0 International,WRFChem MOSAiC run - March 15 to April 30 2020. From https://doi.org/10.1525/elementa.2022.00129,api,True,findable,0.0,0.0,0.0,0.0,0.0,2024-01-22T11:19:08.000Z,2024-01-22T11:19:08.000Z,cern.zenodo,cern,,,,
+10.6084/m9.figshare.22604164,Additional file 1 of Early management of isolated severe traumatic brain injury patients in a hospital without neurosurgical capabilities: a consensus and clinical recommendations of the World Society of Emergency Surgery (WSES),figshare,2023.0,,Text,Creative Commons Attribution 4.0 International,Additional file 1. Appendix 1. Consensus participants.,mds,True,findable,0.0,0.0,53.0,1.0,0.0,2023-04-13T10:34:17.000Z,2023-04-13T10:34:18.000Z,figshare.ars,otjm,"Medicine,Genetics,FOS: Biological sciences,Molecular Biology,Ecology,Science Policy","[{'subject': 'Medicine'}, {'subject': 'Genetics'}, {'subject': 'FOS: Biological sciences', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': 'Molecular Biology'}, {'subject': 'Ecology'}, {'subject': 'Science Policy'}]",['15123 Bytes'],
+10.26302/sshade/experiment_lb_20210201_001,"NIR reflectance spectrum (i=0°, e=30°) of raw pieces, powdered samples and polished sections of ungrouped carbonaceous chondrites under ambient pressure and temperature",SSHADE/GhoSST (OSUG Data Center),2021.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","NIR reflectance spectrum (i=0°, e=30°) of raw pieces, powdered samples and polished sections of NWA 12957, Chwichiya 002, NWA 11750, NWA 11086, Aydar 003, NWA 5958,El Medano 100, El Medano 200, Acfer 094, Dhofar 2066, Kakangari, Los Vientos 200, NWA 8781, NWA 12472, NWA 12474, Sierra Gorda 009, Awsserd, Los Vientos 051, NWA 12334, NWA 12480, Coolidge and Jiddat Al Harasis 846 under ambient pressure and temperature",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2021-02-09T07:16:26.000Z,2021-02-09T07:16:27.000Z,inist.sshade,mgeg,"extraterrestrial,carbonaceous chondrite,C ungrouped,complex organic-mineral mix,matrix NWA12957,complex mineral mix,chondrules NWA12957,CAIs NWA12957,matrix Chwichiya002,chondrules Chwichiya002,CAIs Chwichiya002,matrix NWA11750,chondrules NWA11750,CAIs NWA11750,CM,matrix NWA11086,chondrules NWA11086,CAIs NWA11086,matrix Aydar003,chondrules Aydar003,CAIs Aydar003,matrix NWA5958,chondrules NWA5958,CAIs NWA5958,matrix ElMédano100,chondrules ElMédano100,CAIs ElMédano100,matrix Dhofar2066,chondrules Dhofar2066,CAIs Dhofar2066,Kakangari-like chondrite,K,matrix Kakangari,chondrules Kakangari,CAIs Kakangari,CH,matrix LosVientos200,chondrules LosVientos200,CAIs LosVientos200,matrix NWA8781,chondrules NWA8781,CAIs NWA8781,CR,matrix NWA12474,chondrules NWA12474,CAIs NWA12474,ungrouped chondrite,not classified,matrix SierraGorda009,chondrules SierraGorda009,CAIs SierraGorda009,Rumuruti-like chondrite,R,matrix Awsserd,chondrules Awsserd,CAIs Awsserd,matrix NWA12472,chondrules NWA12472,CAIs NWA12472,matrix LosVientos051,chondrules LosVientos051,CAIs LosVientos051,ordinary chondrite,LL,matrix NWA12334,chondrules NWA12334,CAIs NWA12334,None,metal JAH846,silicates JAH846,primitive achondrite,acapulcoite,metal NWA12480,silicates NWA12480,ungrouped,matrix Acfer094,chondrules Acfer094,CAIs Acfer094,matrix ElMedano200,chondrules ElMedano200,CAIs ElMedano200,matrix Coolidge,chondrules Coolidge,CAIs Coolidge,laboratory measurement,bidirectional reflection,macroscopic,Vis,Visible,NIR,Near-Infrared,reflectance factor","[{'subject': 'extraterrestrial'}, {'subject': 'carbonaceous chondrite'}, {'subject': 'C ungrouped'}, {'subject': 'complex organic-mineral mix'}, {'subject': 'matrix NWA12957'}, {'subject': 'complex mineral mix'}, {'subject': 'chondrules NWA12957'}, {'subject': 'CAIs NWA12957'}, {'subject': 'matrix Chwichiya002'}, {'subject': 'chondrules Chwichiya002'}, {'subject': 'CAIs Chwichiya002'}, {'subject': 'matrix NWA11750'}, {'subject': 'chondrules NWA11750'}, {'subject': 'CAIs NWA11750'}, {'subject': 'CM'}, {'subject': 'matrix NWA11086'}, {'subject': 'chondrules NWA11086'}, {'subject': 'CAIs NWA11086'}, {'subject': 'matrix Aydar003'}, {'subject': 'chondrules Aydar003'}, {'subject': 'CAIs Aydar003'}, {'subject': 'matrix NWA5958'}, {'subject': 'chondrules NWA5958'}, {'subject': 'CAIs NWA5958'}, {'subject': 'matrix ElMédano100'}, {'subject': 'chondrules ElMédano100'}, {'subject': 'CAIs ElMédano100'}, {'subject': 'matrix Dhofar2066'}, {'subject': 'chondrules Dhofar2066'}, {'subject': 'CAIs Dhofar2066'}, {'subject': 'Kakangari-like chondrite'}, {'subject': 'K'}, {'subject': 'matrix Kakangari'}, {'subject': 'chondrules Kakangari'}, {'subject': 'CAIs Kakangari'}, {'subject': 'CH'}, {'subject': 'matrix LosVientos200'}, {'subject': 'chondrules LosVientos200'}, {'subject': 'CAIs LosVientos200'}, {'subject': 'matrix NWA8781'}, {'subject': 'chondrules NWA8781'}, {'subject': 'CAIs NWA8781'}, {'subject': 'CR'}, {'subject': 'matrix NWA12474'}, {'subject': 'chondrules NWA12474'}, {'subject': 'CAIs NWA12474'}, {'subject': 'ungrouped chondrite'}, {'subject': 'not classified'}, {'subject': 'matrix SierraGorda009'}, {'subject': 'chondrules SierraGorda009'}, {'subject': 'CAIs SierraGorda009'}, {'subject': 'Rumuruti-like chondrite'}, {'subject': 'R'}, {'subject': 'matrix Awsserd'}, {'subject': 'chondrules Awsserd'}, {'subject': 'CAIs Awsserd'}, {'subject': 'matrix NWA12472'}, {'subject': 'chondrules NWA12472'}, {'subject': 'CAIs NWA12472'}, {'subject': 'matrix LosVientos051'}, {'subject': 'chondrules LosVientos051'}, {'subject': 'CAIs LosVientos051'}, {'subject': 'ordinary chondrite'}, {'subject': 'LL'}, {'subject': 'matrix NWA12334'}, {'subject': 'chondrules NWA12334'}, {'subject': 'CAIs NWA12334'}, {'subject': 'None'}, {'subject': 'metal JAH846'}, {'subject': 'silicates JAH846'}, {'subject': 'primitive achondrite'}, {'subject': 'acapulcoite'}, {'subject': 'metal NWA12480'}, {'subject': 'silicates NWA12480'}, {'subject': 'ungrouped'}, {'subject': 'matrix Acfer094'}, {'subject': 'chondrules Acfer094'}, {'subject': 'CAIs Acfer094'}, {'subject': 'matrix ElMedano200'}, {'subject': 'chondrules ElMedano200'}, {'subject': 'CAIs ElMedano200'}, {'subject': 'matrix Coolidge'}, {'subject': 'chondrules Coolidge'}, {'subject': 'CAIs Coolidge'}, {'subject': 'laboratory measurement'}, {'subject': 'bidirectional reflection'}, {'subject': 'macroscopic'}, {'subject': 'Vis'}, {'subject': 'Visible'}, {'subject': 'NIR'}, {'subject': 'Near-Infrared'}, {'subject': 'reflectance factor'}]",['60 spectra'],['ASCII']
+10.26302/sshade/experiment_cl_20180316_02,MIR reflectance spectrum of a QUE97990 CM chondrite pellet,SSHADE/DAYSY (OSUG Data Center),2022.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","Average MIR reflectance spectrum of a pellet of QUE97990 CM chondrite, obtained by hyperspectral imaging",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2022-06-01T21:24:24.000Z,2022-06-01T21:24:24.000Z,inist.sshade,mgeg,"extraterrestrial,carbonaceous chondrite,CM,complex organic-mineral mix,matrix QUE97990,complex mineral mix,chondrules QUE97990,CAIs QUE97990,laboratory measurement,confocal reflection,micro-imaging,MIR,Mid-Infrared,normalized reflectance","[{'subject': 'extraterrestrial'}, {'subject': 'carbonaceous chondrite'}, {'subject': 'CM'}, {'subject': 'complex organic-mineral mix'}, {'subject': 'matrix QUE97990'}, {'subject': 'complex mineral mix'}, {'subject': 'chondrules QUE97990'}, {'subject': 'CAIs QUE97990'}, {'subject': 'laboratory measurement'}, {'subject': 'confocal reflection'}, {'subject': 'micro-imaging'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'normalized reflectance'}]",['1 spectrum'],['ASCII']
+10.26302/sshade/experiment_sb_20200629_001,Optical constants in the MIR and FIR for oriented natural anatase and brookite crystals,SSHADE/DOCCD (OSUG Data Center),2020.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2020-07-14T08:41:37.000Z,2020-07-14T08:41:39.000Z,inist.sshade,mgeg,"natural terrestrial,oxide-hydroxide,Anatase,Brookite,laboratory measurement,specular reflection,macroscopic,MIR,Mid-Infrared,FIR,Far-Infrared,optical constants","[{'subject': 'natural terrestrial'}, {'subject': 'oxide-hydroxide'}, {'subject': 'Anatase'}, {'subject': 'Brookite'}, {'subject': 'laboratory measurement'}, {'subject': 'specular reflection'}, {'subject': 'macroscopic'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'FIR'}, {'subject': 'Far-Infrared'}, {'subject': 'optical constants'}]",['5 spectra'],['ASCII']
+10.26302/sshade/experiment_gl_20150105_1,Mid-infrared diffuse reflectance experiment with chlorite (donbassite) heated in-situ from 25 to 860°C,SSHADE/LSD (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2022-11-04T08:17:23.000Z,2022-11-04T08:17:24.000Z,inist.sshade,mgeg,"mineral,natural terrestrial,phyllosilicate,donbassite,commercial,elemental solid,Synthetic diamond powder,laboratory measurement,diffuse reflection,macroscopic,MIR,Mid-Infrared,absorbance","[{'subject': 'mineral'}, {'subject': 'natural terrestrial'}, {'subject': 'phyllosilicate'}, {'subject': 'donbassite'}, {'subject': 'commercial'}, {'subject': 'elemental solid'}, {'subject': 'Synthetic diamond powder'}, {'subject': 'laboratory measurement'}, {'subject': 'diffuse reflection'}, {'subject': 'macroscopic'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'absorbance'}]",['4 spectra'],['ASCII']
+10.26302/sshade/bandlist_raman_eitelite,Raman bandlist of Eitelite,SSHADE/BANDLIST (OSUG Data Center),2023.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",MIR-FIR Raman bandlist of synthetic and natural Eitelite at 295K,mds,True,findable,0.0,0.0,5.0,0.0,0.0,2023-08-30T22:25:03.000Z,2023-08-30T22:25:03.000Z,inist.sshade,mgeg,"Eitelite,Sodium cation,Magnesium(II) cation,Carbonate anion,Sodium(1+) cation,Magnesium(2+) cation,17341-25-2,22537-22-0,Na+,Mg2+,(CO3)2-,Na2Mg(CO3)2,Eitelite,non-silicate mineral,carbonate,carbonates, nitrates, borates,anhydrous carbonates,-Eitelite- group,14.03.02.01,05.AC.05,Raman scattering,FIR,MIR,band frequency,band width,band intensity,transition and vibration modes","[{'subject': 'Eitelite', 'subjectScheme': 'name'}, {'subject': 'Sodium cation', 'subjectScheme': 'name'}, {'subject': 'Magnesium(II) cation', 'subjectScheme': 'name'}, {'subject': 'Carbonate anion', 'subjectScheme': 'name'}, {'subject': 'Sodium(1+) cation', 'subjectScheme': 'IUPAC name'}, {'subject': 'Magnesium(2+) cation', 'subjectScheme': 'IUPAC name'}, {'subject': '17341-25-2', 'subjectScheme': 'CAS number'}, {'subject': '22537-22-0', 'subjectScheme': 'CAS number'}, {'subject': 'Na+', 'subjectScheme': 'formula'}, {'subject': 'Mg2+', 'subjectScheme': 'formula'}, {'subject': '(CO3)2-', 'subjectScheme': 'formula'}, {'subject': 'Na2Mg(CO3)2', 'subjectScheme': 'formula'}, {'subject': 'Eitelite', 'subjectScheme': 'IMA name'}, {'subject': 'non-silicate mineral', 'subjectScheme': 'mineral class'}, {'subject': 'carbonate', 'subjectScheme': 'compound type'}, {'subject': 'carbonates, nitrates, borates', 'subjectScheme': 'Dana class'}, {'subject': 'anhydrous carbonates', 'subjectScheme': 'Dana class'}, {'subject': '-Eitelite- group', 'subjectScheme': 'Dana group'}, {'subject': '14.03.02.01', 'subjectScheme': 'Dana code'}, {'subject': '05.AC.05', 'subjectScheme': 'Strunz code'}, {'subject': 'Raman scattering', 'subjectScheme': 'variables'}, {'subject': 'FIR', 'subjectScheme': 'variables'}, {'subject': 'MIR', 'subjectScheme': 'variables'}, {'subject': 'band frequency', 'subjectScheme': 'variables'}, {'subject': 'band width', 'subjectScheme': 'variables'}, {'subject': 'band intensity', 'subjectScheme': 'variables'}, {'subject': 'transition and vibration modes', 'subjectScheme': 'variables'}]",,['ASCII']
+10.5281/zenodo.10485579,"Fig. 3 in The chloroplast membrane associated ceQORH putative quinone oxidoreductase reduces long-chain, stress-related oxidized lipids",Zenodo,2016.0,,Image,License Not Specified,"Fig. 3. HPLC analyses of the reaction catalyzed by ceQORH in the presence of trans- 1,3-diphenyl-2-propenone and NADPH at 312 nm (maximum of absorption of bisphenylpropenone). (A) ceQORH activity was measured as a function of the trans- 1,3-diphenyl-2-propenone concentration in the presence of NADPH (k = 3.6 ± 1.5 s –1, K = 14 ± 2 µM). (B) HPLC profile of 1 nmol of trans-1,3- cat M diphenyl-2-propenone. The alkene function is responsible of the absorption at 312 nm. (C) Chromatograms of the complete reaction mixture at different reaction times. The decrease in absorbance at 312 nm demonstrates that CeQORH reduces the alkene function. (D) Same as in C with the absorption measured at 250 nm showing the time dependent appearence of a novel product eluted earlier. The absorption of the peak eluted at 3.5 min does not change at 312 nm or 250 nm and most certainly corresponds to the cis-isomer of 1,3-bisphenyl-2-propenone.",api,True,findable,0.0,0.0,0.0,0.0,0.0,2024-01-11T04:59:38.000Z,2024-01-11T04:59:38.000Z,cern.zenodo,cern,"Biodiversity,Taxonomy","[{'subject': 'Biodiversity'}, {'subject': 'Taxonomy'}]",,
+10.26302/sshade/experiment_dt_20170215_001,"Pb L3 edge XAS fluorescence of lead(II) solution at hydrothermal conditions: 800 bar, 30 to 489°C",SSHADE/FAME (OSUG Data Center),2022.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","Chloride, bromide and bisulfide bearing solutions; temperature varying from 30 to 489°C",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2022-10-10T20:15:21.000Z,2022-10-10T20:15:22.000Z,inist.sshade,mgeg,"laboratory,liquid solution,Lead(II) solution at hydrothermal conditions: PbCl2(s) in 0.9m NaCl + 0.1m HCl (ESRF-Sol1),Lead(II) solution at hydrothermal conditions: PbCl2(s) in 0.1m HCl (ESRF-Sol2),Lead(II) solution at hydrothermal conditions: Pb 0.014m, Cl 9.728m, Li 9.7m, HCl 0.5m (ESRF-Sol5),Lead(II) solution at hydrothermal conditions: PbBr2(s) in 0.9m NaBr + 0.1m HBr (ESRF-Sol6),Lead(II) solution at hydrothermal conditions: PbS(s) in 1m NaHS + 2.2mg S (ESRF-Sol7),Lead(II) solution at hydrothermal conditions: Pb 0.026m, Br 3.752m, Na 3.7m, HBr 0.1m (ESRF-Sol9),Lead(II) solution at hydrothermal conditions: PbBr2(s) in 0.1m HBr (ESRF-Sol12),laboratory measurement,fluorescence emission,None,hard X,hard X-rays","[{'subject': 'laboratory'}, {'subject': 'liquid solution'}, {'subject': 'Lead(II) solution at hydrothermal conditions: PbCl2(s) in 0.9m NaCl + 0.1m HCl (ESRF-Sol1)'}, {'subject': 'Lead(II) solution at hydrothermal conditions: PbCl2(s) in 0.1m HCl (ESRF-Sol2)'}, {'subject': 'Lead(II) solution at hydrothermal conditions: Pb 0.014m, Cl 9.728m, Li 9.7m, HCl 0.5m (ESRF-Sol5)'}, {'subject': 'Lead(II) solution at hydrothermal conditions: PbBr2(s) in 0.9m NaBr + 0.1m HBr (ESRF-Sol6)'}, {'subject': 'Lead(II) solution at hydrothermal conditions: PbS(s) in 1m NaHS + 2.2mg S (ESRF-Sol7)'}, {'subject': 'Lead(II) solution at hydrothermal conditions: Pb 0.026m, Br 3.752m, Na 3.7m, HBr 0.1m (ESRF-Sol9)'}, {'subject': 'Lead(II) solution at hydrothermal conditions: PbBr2(s) in 0.1m HBr (ESRF-Sol12)'}, {'subject': 'laboratory measurement'}, {'subject': 'fluorescence emission'}, {'subject': 'None'}, {'subject': 'hard X'}, {'subject': 'hard X-rays'}]",['42 spectra'],['ASCII']
+10.15778/resif.1n2015,French Landslide Observatory – OMIV (Temporary data) (MT-campagne) (RESIF - SISMOB),RESIF - Réseau Sismologique et géodésique Français,2015.0,en,Dataset,"Open Access,Creative Commons Attribution 4.0 International","This seismological network includes several independent sites of gravitational instabilities in France.These sites corresponds to temporary acquisitions, funded by several independent projects, in relation with the French Landslide Observatory – OMIV. OMIV – Observatoire Multi-disciplinaire des Instabilités de Versants) is a service (SNO – Service National d'Observation) of the French Institute for Earth Sciences and Astronomy (INSU) of the National Center for Scientific Research (CNRS). The sites being studied are large and continuously active landslides, rocky cliffs affected by recurrent rockfalls, or rock glaciers. The sites are located in moutain or coastal environments. The data collected are devoted to the seismological analysis of gravitational instabilities i.e. landslide endogenous seismicity (e.g. seismic sources related to physical processes triggered by the deformation of unstable slopes) and to the production of landslide seismic sources catalogues. """,mds,True,findable,0.0,0.0,0.0,1.0,0.0,2020-05-18T10:30:53.000Z,2020-05-18T10:31:23.000Z,inist.resif,vcob,"natural hazard,landslide,rockfall,environmental seismology","[{'subject': 'natural hazard'}, {'subject': 'landslide'}, {'subject': 'rockfall'}, {'subject': 'environmental seismology'}]","['530 Gb, growing']","['Miniseed data', 'stationXML metadata']"
+10.26302/sshade/experiment_bms_20150101_001,VUV absorbance spectra between 10 and 120 K of amorphous CH3CN deposited at 10 K,SSHADE/ACID (OSUG Data Center),2019.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",VUV absorbance spectra between 10 and 120 K of amorphous CH3CN deposited at 10 K,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2021-03-01T20:12:12.000Z,2021-03-01T20:12:14.000Z,inist.sshade,mgeg,"laboratory,organic molecular solid,amorphous CH3CN ice,laboratory measurement,transmission,macroscopic,VUV,Vacuum Ultraviolet,absorbance","[{'subject': 'laboratory'}, {'subject': 'organic molecular solid'}, {'subject': 'amorphous CH3CN ice'}, {'subject': 'laboratory measurement'}, {'subject': 'transmission'}, {'subject': 'macroscopic'}, {'subject': 'VUV'}, {'subject': 'Vacuum Ultraviolet'}, {'subject': 'absorbance'}]",['4 spectra'],['ASCII']
+10.6084/m9.figshare.22625632,"Additional file 9 of A multicentre, patient- and assessor-blinded, non-inferiority, randomised and controlled phase II trial to compare standard and torque teno virus-guided immunosuppression in kidney transplant recipients in the first year after transplantation: TTVguideIT",figshare,2023.0,,Text,Creative Commons Attribution 4.0 International,Additional file 9.,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-04-13T18:56:14.000Z,2023-04-13T18:56:15.000Z,figshare.ars,otjm,"Immunology,FOS: Clinical medicine","[{'subject': 'Immunology'}, {'subject': 'FOS: Clinical medicine', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}]",['1022601 Bytes'],
+10.15778/resif.yv2011,"RHUM-RUM experiment, 2011-2015, code YV (Réunion Hotspot and Upper Mantle – Réunion's Unterer Mantel) funded by ANR, DFG, CNRS-INSU, IPEV, TAAF, instrumented by DEPAS, INSU-OBS, AWI and the Universities of Muenster, Bonn, La Réunion",RESIF - Réseau Sismologique et géodésique Français,2017.0,en,Dataset,"Open Access,Creative Commons Attribution 4.0 International","RHUM-RUM (Réunion Hotspot and Upper Mantle - Réunions Unterer Mantel) is a French-German passive seismic experiment designed to image an oceanic mantle plume – or lack of plume – from crust to core beneath La Réunion Island, and to understand these results in terms of material, heat flow and plume dynamics. La Réunion hotspot is one of the most active volcanoes in the world, and its hotspot track leads to the Deccan Traps of India, one of the largest flood basalt provinces on Earth, which erupted 65 Ma ago. The genesis and the origin at depth of the mantle upwelling and of the hotspot are still very controversial. In the RHUM-RUM project, 57 German and French ocean-bottom seismometers (OBS) have been deployed in october 2012 over an area of 2000 km x 2000 km2 centered on La Réunion Island, using the French “Marion Dufresne” vessel and have been recovered in October 2013 by the German “Meteor” vessel. The one-year OBS deployment (Oct. 2012 – Oct. 2013) is augmented by terrestrial deployments in the Iles Eparses in the Mozambique Channel, in Madagascar, Seychelles, Mauritius, Rodrigues and La Réunion islands. A significant number of OBS has been also distributed along the Central and South West Indian Ridges to image the lower-mantle beneath the hotspot, but also to provide independent opportunity for the study of these slow to ultra-slow ridges and of possible plume-ridge interactions, in particular beneath the Rodrigues ridge that could sign a physical link between the Réunion hotspot and the Central Indian Ridge.",mds,True,findable,0.0,0.0,1.0,10.0,0.0,2015-04-01T15:13:44.000Z,2015-04-01T15:13:44.000Z,inist.resif,vcob,"Réunion Hotspot,Piton de la Fournaise volcano,Mantle plume,Lithosphere and Asthenosphere,Upper and lower mantle tomography,Seismic anisotropy and mantle flow,Body and surface wave seismology,Ocean Bottom seismometers,Mascareignes basin,Central and South-West Indian ridges,Rodrigues ridge","[{'subject': 'Réunion Hotspot'}, {'subject': 'Piton de la Fournaise volcano'}, {'subject': 'Mantle plume'}, {'subject': 'Lithosphere and Asthenosphere'}, {'subject': 'Upper and lower mantle tomography'}, {'subject': 'Seismic anisotropy and mantle flow'}, {'subject': 'Body and surface wave seismology'}, {'subject': 'Ocean Bottom seismometers'}, {'subject': 'Mascareignes basin'}, {'subject': 'Central and South-West Indian ridges'}, {'subject': 'Rodrigues ridge'}]",['Approx. 2.5 Tb;78 stations'],"['miniseed data', 'stationXML metadata']"
+10.26302/sshade/experiment_cl_20181127_01,Ion irradiation ($He^+$) of an Alais meteorite pellet probed by Vis-NIR spectroscopy,SSHADE/DAYSY (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","Vis-NIR spectra of Alais meteorite pellet, before and after ion irradiation at different doses.",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2022-05-27T10:51:47.000Z,2022-05-27T10:51:48.000Z,inist.sshade,mgeg,"extraterrestrial,carbonaceous chondrite,CI,complex organic-mineral mix,matrix Alais,complex mineral mix,chondrules Alais,CAIs Alais,laboratory measurement,bidirectional reflection,macroscopic,Vis,Visible,reflectance factor","[{'subject': 'extraterrestrial'}, {'subject': 'carbonaceous chondrite'}, {'subject': 'CI'}, {'subject': 'complex organic-mineral mix'}, {'subject': 'matrix Alais'}, {'subject': 'complex mineral mix'}, {'subject': 'chondrules Alais'}, {'subject': 'CAIs Alais'}, {'subject': 'laboratory measurement'}, {'subject': 'bidirectional reflection'}, {'subject': 'macroscopic'}, {'subject': 'Vis'}, {'subject': 'Visible'}, {'subject': 'reflectance factor'}]",['5 spectra'],['ASCII']
+10.26302/sshade/experiment_bs_20201114_016,"Near-infrared reflectance spectra at low temperature (300-80K) of Ammonium carbonate [(NH4)2CO3] powders with three grain size ranges (32-80, 80-125 and 125-150µm)",SSHADE/CSS (OSUG Data Center),2022.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",Near-infrared reflectance spectra at low temperature (290-80K) of Ammonium carbonate powder [(NH4)2CO3] with 32-80 µm grain size and at room temperature (300K) with 80-125µm and 125-150µm grain sizes,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2022-04-23T08:16:36.000Z,2022-04-23T08:16:37.000Z,inist.sshade,mgeg,"commercial,carbonate,Ammonium carbonate,laboratory measurement,bidirectional reflection,macroscopic,NIR,Near-Infrared,reflectance factor","[{'subject': 'commercial'}, {'subject': 'carbonate'}, {'subject': 'Ammonium carbonate'}, {'subject': 'laboratory measurement'}, {'subject': 'bidirectional reflection'}, {'subject': 'macroscopic'}, {'subject': 'NIR'}, {'subject': 'Near-Infrared'}, {'subject': 'reflectance factor'}]",['18 spectra'],['ASCII']
+10.26302/sshade/experiment_bs_20120924_001,Mid-IR Transmission spectra of crystalline Ih H2O ice at different temperatures (145K to 17K),SSHADE/GhoSST (OSUG Data Center),2019.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",Mid-IR Transmission spectra of crystalline Ih H2O ice (0.74µm film) deposited at 145K and measured at different temperatures (145K to 17K),mds,True,findable,0.0,0.0,0.0,0.0,0.0,2019-12-03T08:31:52.000Z,2019-12-03T08:31:52.000Z,inist.sshade,mgeg,"laboratory,inorganic molecular solid,H2O crystalline phase Ih,laboratory measurement,transmission,macroscopic,MIR,Mid-Infrared","[{'subject': 'laboratory'}, {'subject': 'inorganic molecular solid'}, {'subject': 'H2O crystalline phase Ih'}, {'subject': 'laboratory measurement'}, {'subject': 'transmission'}, {'subject': 'macroscopic'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}]",['4 spectra'],['ASCII']
+10.15778/resif.xp2014,Seismic network XP: Volcarray temporary experiment (ISTerre/OVPF(IPGP)),RESIF - Réseau Sismologique et géodésique Français,2014.0,en,Dataset,"Open Access,Creative Commons Attribution 4.0 International","300 autonomous short period vertical seismic stations deployed in 3 sub-networks of 100 sensors each on Piton de la Fournaise volcano (La Réunion Island, Indian Ocean, France) for 1 month. The sensors are Z-Land stations of FairfieldNodal.",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2014-12-08T09:56:45.000Z,2014-12-08T09:56:45.000Z,inist.resif,vcob,"Piton de la Fournaise volcano,Imaging,Ambient noise,Monitoring of volcano activity","[{'subject': 'Piton de la Fournaise volcano'}, {'subject': 'Imaging'}, {'subject': 'Ambient noise'}, {'subject': 'Monitoring of volcano activity'}]",['529 G;152 stations'],"['miniseed data', 'stationXML metadata']"
+10.5281/zenodo.10469400,Ecological histories determine the success of social exploitation,Zenodo,2023.0,en,Dataset,Creative Commons Attribution 4.0 International,"Data and analysis code for the manuscript ""Ecological histories determine the success of social exploitation"" by KA Schaal*, P Manhes*, & GJ Velicer
+
+*shared first-authorship",api,True,findable,0.0,0.0,0.0,0.0,0.0,2024-01-08T11:34:27.000Z,2024-01-08T11:34:27.000Z,cern.zenodo,cern,,,,
+10.26302/sshade/experiment_kd_20220525_002,"Optical constants of Mg- and Fe-rich amorphous silicate Mg$_{(1-x)}$Fe$_x$SiO$_3$, x=0.1 - 0.2 - 0.3 - 0.4, processed samples, 10-300 K, UV-mm range",SSHADE/STOPCODA (OSUG Data Center),2022.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","UV to mm optical constants of four Mg- and Fe-rich amorphous silicates Mg$_{(1-x)}$Fe$_x$SiO$_3$, x=0.1 - 0.2 - 0.3 - 0.4, processed samples, at 10, 100, 200 and 300 K. The optical constants are calculated from mass absorption coefficients measured in the 5 - 1000 µm (2000-10 cm-1) range and extrapolated in the range 0.024 - 5 µm and 1000 - 100000 µm.",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2022-05-31T13:18:49.000Z,2022-05-31T13:18:50.000Z,inist.sshade,mgeg,"solid,laboratory,non-oxide ceramic,Amorphous silicate Mg$_{(1-x)}$Fe$_x$SiO$_3$, x=0.1,commercial,homopolymer,Polyethylene HDPE,bromide,Potassium bromide KBr,Amorphous silicate Mg$_{(1-x)}$Fe$_x$SiO$_3$, x=0.2,Amorphous silicate Mg$_{(1-x)}$Fe$_x$SiO$_3$, x=0.3,Amorphous silicate Mg$_{(1-x)}$Fe$_x$SiO$_3$, x=0.4,laboratory measurement,numerical extrapolation,macroscopic,UV,Ultraviolet,Vis,Visible,NIR,Near-Infrared,MIR,Mid-Infrared,FIR,Far-Infrared,sub-mm,mm,millimeter wave,cm,centimeter wave,optical constants","[{'subject': 'solid'}, {'subject': 'laboratory'}, {'subject': 'non-oxide ceramic'}, {'subject': 'Amorphous silicate Mg$_{(1-x)}$Fe$_x$SiO$_3$, x=0.1'}, {'subject': 'commercial'}, {'subject': 'homopolymer'}, {'subject': 'Polyethylene HDPE'}, {'subject': 'bromide'}, {'subject': 'Potassium bromide KBr'}, {'subject': 'Amorphous silicate Mg$_{(1-x)}$Fe$_x$SiO$_3$, x=0.2'}, {'subject': 'Amorphous silicate Mg$_{(1-x)}$Fe$_x$SiO$_3$, x=0.3'}, {'subject': 'Amorphous silicate Mg$_{(1-x)}$Fe$_x$SiO$_3$, x=0.4'}, {'subject': 'laboratory measurement'}, {'subject': 'numerical extrapolation'}, {'subject': 'macroscopic'}, {'subject': 'UV'}, {'subject': 'Ultraviolet'}, {'subject': 'Vis'}, {'subject': 'Visible'}, {'subject': 'NIR'}, {'subject': 'Near-Infrared'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'FIR'}, {'subject': 'Far-Infrared'}, {'subject': 'sub-mm'}, {'subject': 'mm'}, {'subject': 'millimeter wave'}, {'subject': 'cm'}, {'subject': 'centimeter wave'}, {'subject': 'optical constants'}]",['16 spectra'],['ASCII']
+10.26302/sshade/experiment_cl_20181202_04,Ion irradiation ($He^+$) of an Tagish Lake meteorite pellet probed by NIR spectroscopy,SSHADE/DAYSY (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","NIR spectra of Tagish Lake meteorite pellet, before and after ion irradiation at different doses.",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2022-05-27T17:02:29.000Z,2022-05-27T17:02:30.000Z,inist.sshade,mgeg,"extraterrestrial,carbonaceous chondrite,ungrouped,complex organic-mineral mix,matrix TagishLake,complex mineral mix,chondrules TagishLake,CAIs Tagish Lake,laboratory measurement,bidirectional reflection,macroscopic,NIR,Near-Infrared,reflectance factor","[{'subject': 'extraterrestrial'}, {'subject': 'carbonaceous chondrite'}, {'subject': 'ungrouped'}, {'subject': 'complex organic-mineral mix'}, {'subject': 'matrix TagishLake'}, {'subject': 'complex mineral mix'}, {'subject': 'chondrules TagishLake'}, {'subject': 'CAIs Tagish Lake'}, {'subject': 'laboratory measurement'}, {'subject': 'bidirectional reflection'}, {'subject': 'macroscopic'}, {'subject': 'NIR'}, {'subject': 'Near-Infrared'}, {'subject': 'reflectance factor'}]",['5 spectra'],['ASCII']
+10.26302/sshade/experiment_bs_20130120_003,Far-IR optical constants of amorphous H2O Ia at different temperatures and annealing,SSHADE/GhoSST (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","Far-IR optical constants spectra of amorphous H2O Ia at different temperatures (63, 87.5K) and annealing temperatures",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2019-12-28T21:31:36.000Z,2019-12-28T21:31:37.000Z,inist.sshade,mgeg,"laboratory,inorganic molecular solid,H2O amorphous - phase Ia,laboratory measurement,transmission,macroscopic,FIR,Far-Infrared,optical constants","[{'subject': 'laboratory'}, {'subject': 'inorganic molecular solid'}, {'subject': 'H2O amorphous - phase Ia'}, {'subject': 'laboratory measurement'}, {'subject': 'transmission'}, {'subject': 'macroscopic'}, {'subject': 'FIR'}, {'subject': 'Far-Infrared'}, {'subject': 'optical constants'}]",['2 spectra'],['ASCII']
+10.6084/m9.figshare.c.6804540,Pneumocystis jirovecii pneumonia in intensive care units: a multicenter study by ESGCIP and EFISG,figshare,2023.0,,Collection,Creative Commons Attribution 4.0 International,"Abstract Background Pneumocystis jirovecii pneumonia (PJP) is an opportunistic, life-threatening disease commonly affecting immunocompromised patients. The distribution of predisposing diseases or conditions in critically ill patients admitted to intensive care unit (ICU) and subjected to diagnostic work-up for PJP has seldom been explored. Materials and methods The primary objective of the study was to describe the characteristics of ICU patients subjected to diagnostic workup for PJP. The secondary objectives were: (i) to assess demographic and clinical variables associated with PJP; (ii) to assess the performance of Pneumocystis PCR on respiratory specimens and serum BDG for the diagnosis of PJP; (iii) to describe 30-day and 90-day mortality in the study population. Results Overall, 600 patients were included in the study, of whom 115 had presumptive/proven PJP (19.2%). Only 8.8% of ICU patients subjected to diagnostic workup for PJP had HIV infection, whereas hematological malignancy, solid tumor, inflammatory diseases, and solid organ transplants were present in 23.2%, 16.2%, 15.5%, and 10.0% of tested patients, respectively. In multivariable analysis, AIDS (odds ratio [OR] 3.31; 95% confidence interval [CI] 1.13–9.64, p = 0.029), non-Hodgkin lymphoma (OR 3.71; 95% CI 1.23–11.18, p = 0.020), vasculitis (OR 5.95; 95% CI 1.07–33.22, p = 0.042), metastatic solid tumor (OR 4.31; 95% CI 1.76–10.53, p = 0.001), and bilateral ground glass on CT scan (OR 2.19; 95% CI 1.01–4.78, p = 0.048) were associated with PJP, whereas an inverse association was observed for increasing lymphocyte cell count (OR 0.64; 95% CI 0.42–1.00, p = 0.049). For the diagnosis of PJP, higher positive predictive value (PPV) was observed when both respiratory Pneumocystis PCR and serum BDG were positive compared to individual assay positivity (72% for the combination vs. 63% for PCR and 39% for BDG). Cumulative 30-day mortality and 90-day mortality in patients with presumptive/proven PJP were 52% and 67%, respectively. Conclusion PJP in critically ill patients admitted to ICU is nowadays most encountered in non-HIV patients. Serum BDG when used in combination with respiratory Pneumocystis PCR could help improve the certainty of PJP diagnosis.",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-08-25T03:21:17.000Z,2023-08-25T03:21:17.000Z,figshare.ars,otjm,"Medicine,Biotechnology,Immunology,FOS: Clinical medicine,Biological Sciences not elsewhere classified,Cancer,Science Policy,Mental Health,Infectious Diseases,FOS: Health sciences,Virology","[{'subject': 'Medicine'}, {'subject': 'Biotechnology'}, {'subject': 'Immunology'}, {'subject': 'FOS: Clinical medicine', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': 'Biological Sciences not elsewhere classified'}, {'subject': 'Cancer'}, {'subject': 'Science Policy'}, {'subject': 'Mental Health'}, {'subject': 'Infectious Diseases'}, {'subject': 'FOS: Health sciences', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': 'Virology'}]",,
+10.5281/zenodo.10523321,Supplementary data to Frasson et al. 2023,Zenodo,2024.0,en,Dataset,Creative Commons Attribution 4.0 International,"Supplementary data for Frasson et al. 2023 submitted to Solid Earth. The data consist of full snapshots of the geoids, topography, CMB heat flux, and composition at the CMB for the six cases of the study; the PCA outputs for the six cases; and movies showing the time evolutions of the outputs in the mantle convection models.
+
+ 
+
+The full snapshots are given in HDF5 format, with one file per time step. They can be found in the archives MF.zip and MC.zip for the MF model and the MC model respectively. The files contain:
+
+
+
+The fields in the physical space. The first coordinate is the latitude, the second coordinate is the longitude (dataset ""data"").
+
+The latitudes and longitudes associated with the fields (datasets ""latitude"" and ""longitude"").
+
+Some information regarding the snapshots (attributes ""Time (Myr)"", ""Model"", ""Case"", ""Correction"", and ""Unit"").
+
+
+The files are called ""name_xxxx.h5"", where xxxx stands for the time in Myr before the end of the simulation.The names of the files are:
+
+
+
+qcmb: CMB heat flux
+
+geoid: Total geoid
+
+geoid_nolvv: No LVVs geoid
+
+topo: Topography
+
+prim: Composition at the CMB
+
+
+ 
+
+The PCA outputs are given in HDF5 format. Each file has an ""outputs"" and a ""grid"" group. The ""outputs"" section gives:
+
+
+
+The average heat flux pattern. The first coordinate is the latitude, the second coordinate is the longitude (dataset ""average"").
+
+The list of patterns for each PCA component in physical space. The first coordinate is the latitude, the second coordinate is the longitude (dataset ""pattern"").
+
+The time-dependent weight of the components. The first coordinate is the time, the second coordinate is the component number (dataset ""weights"").
+
+The singular values of the components  (dataset ""singular values"").
+
+The time in Myr (dataset ""Time"").
+
+The component numbers (dataset ""components"").
+
+
+The ""grid"" group gives the latitudes (dataset ""latitude"") and the longitudes (dataset ""longitude"") associated with the patterns.
+
+ 
+
+Description of the movies:
+
+
+
+outputs_MF: As in Fig. 2 in Frasson et al. 2023.
+
+outputs_MC: As in Fig. 3 in Frasson et al. 2023.
+
+qcmb_MF: CMB heat flux in cases MF0, MF1, MF2, and MF* in a Mollweide projection. Black lines delineate the edges of basal chemical piles.
+
+qcmb_MC: CMB heat flux in cases MC0 and MC1 in a Mollweide projection. Black lines delineate the edges of basal chemical piles.",api,True,findable,0.0,0.0,0.0,0.0,0.0,2024-01-18T13:41:42.000Z,2024-01-18T13:41:42.000Z,cern.zenodo,cern,,,,
+10.26302/sshade/experiment_zy_20180216_001,VIS-NIR reflectance spectra of water frost condensed at the surface of a piece of compact CO2 ice,SSHADE/BYPASS (OSUG Data Center),2023.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","A piece of compact CO2 ice (commercial slab) was exposed to humid air outdoors (93% RH), resulting in the inhomogeneous deposition of water frost at the surface. Average reflectance spectra over three different regions of interest were then calculated. Vis multispectral + NIR low resolution and Vis-NIR high resolution spectra.",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-04-28T13:54:47.000Z,2023-04-28T13:54:47.000Z,inist.sshade,mgeg,"laboratory measurement,biconical reflection,imaging,Vis,Visible,NIR,Near-Infrared,reflectance factor,H2O ice,solid CO2,solid,laboratory,commercial,inorganic molecular solid","[{'subject': 'laboratory measurement', 'subjectScheme': 'main'}, {'subject': 'biconical reflection', 'subjectScheme': 'main'}, {'subject': 'imaging', 'subjectScheme': 'main'}, {'subject': 'Vis', 'subjectScheme': 'var'}, {'subject': 'Visible', 'subjectScheme': 'var'}, {'subject': 'NIR', 'subjectScheme': 'var'}, {'subject': 'Near-Infrared', 'subjectScheme': 'var'}, {'subject': 'reflectance factor', 'subjectScheme': 'var'}, {'subject': 'H2O ice', 'subjectScheme': 'name'}, {'subject': 'solid CO2', 'subjectScheme': 'name'}, {'subject': 'solid', 'subjectScheme': 'family'}, {'subject': 'laboratory', 'subjectScheme': 'origin'}, {'subject': 'commercial', 'subjectScheme': 'origin'}, {'subject': 'inorganic molecular solid', 'subjectScheme': 'compound type'}]",['6 spectra'],['ASCII']
+10.26302/sshade/experiment_jg_20090125_001,"Vis-NIR reflectance spectra of Udokan (Siberia, Russia) basalt",SSHADE/SOSYPOL (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",Vis-NIR reflectance spectra of the Udokan basalts altered in cold and arid environment (Siberia). The samples were collected along lava flow. The experiment contains spectra of the surface of the samples.,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2019-12-09T05:09:40.000Z,2019-12-09T05:09:41.000Z,inist.sshade,mgeg,"natural terrestrial,nesosilicate,olivine,inosilicate,pyroxenes,tektosilicate,plagioclases,phyllosilicate,smectites,silicate,iddingsite,carbonate,calcite,zeolites,oxide-hydroxide,ferrihydrite,laboratory measurement,bidirectional reflection,macroscopic,Vis,Visible,NIR,Near-Infrared,bidirectional reflectance","[{'subject': 'natural terrestrial'}, {'subject': 'nesosilicate'}, {'subject': 'olivine'}, {'subject': 'inosilicate'}, {'subject': 'pyroxenes'}, {'subject': 'tektosilicate'}, {'subject': 'plagioclases'}, {'subject': 'phyllosilicate'}, {'subject': 'smectites'}, {'subject': 'silicate'}, {'subject': 'iddingsite'}, {'subject': 'carbonate'}, {'subject': 'calcite'}, {'subject': 'zeolites'}, {'subject': 'oxide-hydroxide'}, {'subject': 'ferrihydrite'}, {'subject': 'laboratory measurement'}, {'subject': 'bidirectional reflection'}, {'subject': 'macroscopic'}, {'subject': 'Vis'}, {'subject': 'Visible'}, {'subject': 'NIR'}, {'subject': 'Near-Infrared'}, {'subject': 'bidirectional reflectance'}]",['52 spectra'],['ASCII']
+10.6084/m9.figshare.22613069,Additional file 2 of Digital technologies in routine palliative care delivery: an exploratory qualitative study with health care professionals in Germany,figshare,2023.0,,Text,Creative Commons Attribution 4.0 International,Additional file 2. Consolidated criteria for reporting qualitative research.,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-04-13T12:27:56.000Z,2023-04-13T12:27:57.000Z,figshare.ars,otjm,"59999 Environmental Sciences not elsewhere classified,FOS: Earth and related environmental sciences,69999 Biological Sciences not elsewhere classified,FOS: Biological sciences,Cancer,Science Policy","[{'subject': '59999 Environmental Sciences not elsewhere classified', 'schemeUri': 'http://www.abs.gov.au/ausstats/abs@.nsf/0/6BB427AB9696C225CA2574180004463E', 'subjectScheme': 'FOR'}, {'subject': 'FOS: Earth and related environmental sciences', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': '69999 Biological Sciences not elsewhere classified', 'schemeUri': 'http://www.abs.gov.au/ausstats/abs@.nsf/0/6BB427AB9696C225CA2574180004463E', 'subjectScheme': 'FOR'}, {'subject': 'FOS: Biological sciences', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': 'Cancer'}, {'subject': 'Science Policy'}]",['492390 Bytes'],
+10.15778/resif.zo2008,ARC Vanutu temporay experiment (RESIF-SISMOB),RESIF - Réseau Sismologique et géodésique Français,2011.0,en,Other,"Open Access,Creative Commons Attribution 4.0 International",Data were recorded during temporary experiments on the islands of Tanna and Ambrym (Vanuatu) in 2008,mds,True,findable,0.0,0.0,0.0,5.0,0.0,2018-04-11T08:50:36.000Z,2018-04-11T08:50:36.000Z,inist.resif,vcob,"Volcano Seismology,Yasur,Ambrym,Strombolian explosions","[{'subject': 'Volcano Seismology'}, {'subject': 'Yasur'}, {'subject': 'Ambrym'}, {'subject': 'Strombolian explosions'}]",,
+10.26302/sshade/experiment_nf_20220524_0001,MIR absorbance spectra of CH4 ice at 25K for different deposition rates and different thicknesses,SSHADE/SCOOP (OSUG Data Center),2022.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",MIR absorbance spectra of CH4 ice at 25K for different deposition rates (0.17-1.28 nm/s) and different thicknesses (271-4465 nm),mds,True,findable,0.0,0.0,0.0,0.0,0.0,2022-05-25T11:24:07.000Z,2022-05-25T11:24:08.000Z,inist.sshade,mgeg,"laboratory,organic molecular solid,amorphous CH4,laboratory measurement,transmission,macroscopic,MIR,Mid-Infrared,absorbance","[{'subject': 'laboratory'}, {'subject': 'organic molecular solid'}, {'subject': 'amorphous CH4'}, {'subject': 'laboratory measurement'}, {'subject': 'transmission'}, {'subject': 'macroscopic'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'absorbance'}]",['23 spectra'],['ASCII']
+10.26302/sshade/experiment_zy_20180209_000,VIS-NIR reflectance spectra of binary mixtures of CO2 frost (10-100 µm) and fine-grained spherical water ice particles (4.5 µm average diameter),SSHADE/BYPASS (OSUG Data Center),2023.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","CO2 frost (10-100 µm) produced by adiabatic expansion of gas is mixed with variable amounts of fine-grained water ice particles (spherical, type SPIPA-A, 4.5 µm average diameter) and the reflectance measured. Vis multispectral + NIR low resolution and Vis-NIR high resolution spectra.",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-04-28T13:53:30.000Z,2023-04-28T13:53:30.000Z,inist.sshade,mgeg,"laboratory measurement,biconical reflection,imaging,Vis,Visible,NIR,Near-Infrared,reflectance factor,solid CO2,water ice,solid,laboratory,inorganic molecular solid","[{'subject': 'laboratory measurement', 'subjectScheme': 'main'}, {'subject': 'biconical reflection', 'subjectScheme': 'main'}, {'subject': 'imaging', 'subjectScheme': 'main'}, {'subject': 'Vis', 'subjectScheme': 'var'}, {'subject': 'Visible', 'subjectScheme': 'var'}, {'subject': 'NIR', 'subjectScheme': 'var'}, {'subject': 'Near-Infrared', 'subjectScheme': 'var'}, {'subject': 'reflectance factor', 'subjectScheme': 'var'}, {'subject': 'solid CO2', 'subjectScheme': 'name'}, {'subject': 'water ice', 'subjectScheme': 'name'}, {'subject': 'solid', 'subjectScheme': 'family'}, {'subject': 'laboratory', 'subjectScheme': 'origin'}, {'subject': 'inorganic molecular solid', 'subjectScheme': 'compound type'}]",['8 spectra'],['ASCII']
+10.26302/sshade/experiment_ak_20141122_1,Mid-infrared attenuated total reflectance experiment with Ca2+ exchanged less 1 μm size fraction of beidellite (SbCa-1) equilibrated with H2O vapor under variable relative humidity,SSHADE/LSD (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2022-11-04T08:07:15.000Z,2022-11-04T08:07:16.000Z,inist.sshade,mgeg,"natural terrestrial,phyllosilicate,Ca-exchanged beidellite SbCa-1 size-fraction &lt;1 µm,liquid,D2O 99.9 Sigma-Aldrich,laboratory measurement,ATReflection,macroscopic,MIR,Mid-Infrared,corrected ATR absorbance","[{'subject': 'natural terrestrial'}, {'subject': 'phyllosilicate'}, {'subject': 'Ca-exchanged beidellite SbCa-1 size-fraction &lt;1 µm'}, {'subject': 'liquid'}, {'subject': 'D2O 99.9 Sigma-Aldrich'}, {'subject': 'laboratory measurement'}, {'subject': 'ATReflection'}, {'subject': 'macroscopic'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'corrected ATR absorbance'}]",['8 spectra'],['ASCII']
+10.26302/sshade/experiment_dt_20170222_001,Y K edge XAS fluorescence of yttrium(III) solution at hydrothermal conditions: 800 bar 30 to 450°C,SSHADE/FAME (OSUG Data Center),2020.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",Chloride molality varying from 0.03 to 10 m; temperature varying from 25 to 450 °C,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2019-11-15T20:27:18.000Z,2019-11-15T20:27:18.000Z,inist.sshade,mgeg,"laboratory,liquid solution,Yttrium(III) solution at hydrothermal conditions: Y 0.011m Cl 10.02m Li 9.49m HCl 0.5m,Yttrium(III) solution at hydrothermal conditions: Y 0.01m Cl 0.03m HCl 0.002m,Yttrium(III) solution at hydrothermal conditions: Y 0.011m Cl 0.79m HCl 0.75m,Yttrium(III) solution at hydrothermal conditions: Y 0.012m Cl 2.52m Na 1.99m HCl 0.5m,Yttrium(III) solution at hydrothermal conditions: Y 0.92m Cl 2.76m,laboratory measurement,fluorescence emission,None,hard X,hard X-rays","[{'subject': 'laboratory'}, {'subject': 'liquid solution'}, {'subject': 'Yttrium(III) solution at hydrothermal conditions: Y 0.011m Cl 10.02m Li 9.49m HCl 0.5m'}, {'subject': 'Yttrium(III) solution at hydrothermal conditions: Y 0.01m Cl 0.03m HCl 0.002m'}, {'subject': 'Yttrium(III) solution at hydrothermal conditions: Y 0.011m Cl 0.79m HCl 0.75m'}, {'subject': 'Yttrium(III) solution at hydrothermal conditions: Y 0.012m Cl 2.52m Na 1.99m HCl 0.5m'}, {'subject': 'Yttrium(III) solution at hydrothermal conditions: Y 0.92m Cl 2.76m'}, {'subject': 'laboratory measurement'}, {'subject': 'fluorescence emission'}, {'subject': 'None'}, {'subject': 'hard X'}, {'subject': 'hard X-rays'}]",['26 spectra'],['ASCII']
+10.26302/sshade/experiment_cl_20181201_05,Ion irradiation ($He^+$) of an Tagish Lake meteorite pellet probed by Vis-NIR spectroscopy,SSHADE/DAYSY (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","Vis-NIR spectra of Tagish Lake meteorite pellet, before and after ion irradiation at different doses.",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2022-05-27T17:01:05.000Z,2022-05-27T17:01:07.000Z,inist.sshade,mgeg,"extraterrestrial,carbonaceous chondrite,ungrouped,complex organic-mineral mix,matrix TagishLake,complex mineral mix,chondrules TagishLake,CAIs Tagish Lake,laboratory measurement,bidirectional reflection,macroscopic,Vis,Visible,reflectance factor","[{'subject': 'extraterrestrial'}, {'subject': 'carbonaceous chondrite'}, {'subject': 'ungrouped'}, {'subject': 'complex organic-mineral mix'}, {'subject': 'matrix TagishLake'}, {'subject': 'complex mineral mix'}, {'subject': 'chondrules TagishLake'}, {'subject': 'CAIs Tagish Lake'}, {'subject': 'laboratory measurement'}, {'subject': 'bidirectional reflection'}, {'subject': 'macroscopic'}, {'subject': 'Vis'}, {'subject': 'Visible'}, {'subject': 'reflectance factor'}]",['5 spectra'],['ASCII']
+10.6084/m9.figshare.22625635,"Additional file 10 of A multicentre, patient- and assessor-blinded, non-inferiority, randomised and controlled phase II trial to compare standard and torque teno virus-guided immunosuppression in kidney transplant recipients in the first year after transplantation: TTVguideIT",figshare,2023.0,,Text,Creative Commons Attribution 4.0 International,Additional file 10.,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-04-13T18:56:10.000Z,2023-04-13T18:56:10.000Z,figshare.ars,otjm,"Immunology,FOS: Clinical medicine","[{'subject': 'Immunology'}, {'subject': 'FOS: Clinical medicine', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}]",['184741 Bytes'],
+10.26302/sshade/experiment_gs_20170712_002,Ag K edge XAS transmission of AgO,SSHADE/FAME (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2019-12-05T14:00:51.000Z,2019-12-05T14:00:51.000Z,inist.sshade,mgeg,"solid,commercial,non-oxide ceramic,BN powder,metallic alloy,AgO,laboratory measurement,transmission,None,hard X,hard X-rays","[{'subject': 'solid'}, {'subject': 'commercial'}, {'subject': 'non-oxide ceramic'}, {'subject': 'BN powder'}, {'subject': 'metallic alloy'}, {'subject': 'AgO'}, {'subject': 'laboratory measurement'}, {'subject': 'transmission'}, {'subject': 'None'}, {'subject': 'hard X'}, {'subject': 'hard X-rays'}]",['1 spectrum'],['ASCII']
+10.26302/sshade/experiment_lb_20200108_001,"UV-Vis-IR reflectance spectra (i=10°, e=20°, az=180°) of bulk CM and CR chondrites under vacuum",SSHADE/GhoSST (OSUG Data Center),2020.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","UV-Vis-IR reflectance spectra (i=10°, e=20°, az=180°) of bulk CM and CR chondrites under vacuum",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2020-01-08T13:10:53.000Z,2020-01-08T13:10:54.000Z,inist.sshade,mgeg,"extraterrestrial,carbonaceous chondrite,CR,complex organic-mineral mix,matrix EET92159,complex mineral mix,chondrules EET92159,CAIs EET92159,matrix GRA06100 IPAG,chondrules GRA06100 IPAG,CAIs GRA06100 IPAG,matrix GRO03116 IPAG,chondrules GRO03116 IPAG,CAIs GRO03116 IPAG,matrix GRO95577 IPAG,chondrules GRO95577 IPAG,CAIs GRO95577 IPAG,CV,matrix RBT04133 IPAG,chondrules RBT04133 IPAG,CAIs RBT04133 IPAG,CM,matrix ALH83100 IPAG,chondrules ALH83100 IPAG,CAIs ALH83100 IPAG,matrix ALH84044 IPAG,chondrules ALH84044 IPAG,CAIs ALH84044 IPAG,matrix DOM08003 IPAG,chondrules DOM08003 IPAG,CAIs DOM08003 IPAG,matrix LAP02336 IPAG,chondrules LAP02336 IPAG,CAIs LAP02336 IPAG,matrix LAP03718 IPAG,chondrules LAP03718 IPAG,CAIs EET83355 IPAG,matrix LEW85311 IPAG,chondrules LEW85311 IPAG,CAIs LEW85311 IPAG,matrix LEW85312 IPAG,chondrules LEW85312 IPAG,CAIs LEW85312 IPAG,matrix LEW87022 IPAG,chondrules LEW87022 IPAG,CAIs LEW87022 IPAG,matrix LON94101 IPAG,chondrules LON94101 IPAG,CAIs LON94101 IPAG,matrix MCY05230 IPAG,chondrules MCY05230 IPAG,CAIs MCY05230 IPAG,matrix MET01070 IPAG,chondrules MET01070 IPAG,CAIs MET01070 IPAG,matrix QUE97990 IPAG,chondrules QUE97990 IPAG,CAIs QUE97990 IPAG,matrix ALH84033 IPAG,chondrules ALH84033 IPAG,CAIs ALH84033 IPAG,matrix EET87522 IPAG,chondrules EET87522 IPAG,CAIs EET87522 IPAG,matrix MAC88100 IPAG,chondrules MAC88100 IPAG,CAIs MAC88100 IPAG,matrix MIL07700 IPAG,chondrules MIL07700 IPAG,CAIs MIL07700 IPAG,matrix PCA02010 IPAG,chondrules PCA02010 IPAG,CAIs PCA02010 IPAG,matrix PCA02012 IPAG,chondrules PCA02012 IPAG,CAIs PCA02012 IPAG,laboratory measurement,bidirectional reflection,macroscopic,UV,Ultraviolet,Vis,Visible,NIR,Near-Infrared,MIR,Mid-Infrared,FIR,Far-Infrared,reflectance factor","[{'subject': 'extraterrestrial'}, {'subject': 'carbonaceous chondrite'}, {'subject': 'CR'}, {'subject': 'complex organic-mineral mix'}, {'subject': 'matrix EET92159'}, {'subject': 'complex mineral mix'}, {'subject': 'chondrules EET92159'}, {'subject': 'CAIs EET92159'}, {'subject': 'matrix GRA06100 IPAG'}, {'subject': 'chondrules GRA06100 IPAG'}, {'subject': 'CAIs GRA06100 IPAG'}, {'subject': 'matrix GRO03116 IPAG'}, {'subject': 'chondrules GRO03116 IPAG'}, {'subject': 'CAIs GRO03116 IPAG'}, {'subject': 'matrix GRO95577 IPAG'}, {'subject': 'chondrules GRO95577 IPAG'}, {'subject': 'CAIs GRO95577 IPAG'}, {'subject': 'CV'}, {'subject': 'matrix RBT04133 IPAG'}, {'subject': 'chondrules RBT04133 IPAG'}, {'subject': 'CAIs RBT04133 IPAG'}, {'subject': 'CM'}, {'subject': 'matrix ALH83100 IPAG'}, {'subject': 'chondrules ALH83100 IPAG'}, {'subject': 'CAIs ALH83100 IPAG'}, {'subject': 'matrix ALH84044 IPAG'}, {'subject': 'chondrules ALH84044 IPAG'}, {'subject': 'CAIs ALH84044 IPAG'}, {'subject': 'matrix DOM08003 IPAG'}, {'subject': 'chondrules DOM08003 IPAG'}, {'subject': 'CAIs DOM08003 IPAG'}, {'subject': 'matrix LAP02336 IPAG'}, {'subject': 'chondrules LAP02336 IPAG'}, {'subject': 'CAIs LAP02336 IPAG'}, {'subject': 'matrix LAP03718 IPAG'}, {'subject': 'chondrules LAP03718 IPAG'}, {'subject': 'CAIs EET83355 IPAG'}, {'subject': 'matrix LEW85311 IPAG'}, {'subject': 'chondrules LEW85311 IPAG'}, {'subject': 'CAIs LEW85311 IPAG'}, {'subject': 'matrix LEW85312 IPAG'}, {'subject': 'chondrules LEW85312 IPAG'}, {'subject': 'CAIs LEW85312 IPAG'}, {'subject': 'matrix LEW87022 IPAG'}, {'subject': 'chondrules LEW87022 IPAG'}, {'subject': 'CAIs LEW87022 IPAG'}, {'subject': 'matrix LON94101 IPAG'}, {'subject': 'chondrules LON94101 IPAG'}, {'subject': 'CAIs LON94101 IPAG'}, {'subject': 'matrix MCY05230 IPAG'}, {'subject': 'chondrules MCY05230 IPAG'}, {'subject': 'CAIs MCY05230 IPAG'}, {'subject': 'matrix MET01070 IPAG'}, {'subject': 'chondrules MET01070 IPAG'}, {'subject': 'CAIs MET01070 IPAG'}, {'subject': 'matrix QUE97990 IPAG'}, {'subject': 'chondrules QUE97990 IPAG'}, {'subject': 'CAIs QUE97990 IPAG'}, {'subject': 'matrix ALH84033 IPAG'}, {'subject': 'chondrules ALH84033 IPAG'}, {'subject': 'CAIs ALH84033 IPAG'}, {'subject': 'matrix EET87522 IPAG'}, {'subject': 'chondrules EET87522 IPAG'}, {'subject': 'CAIs EET87522 IPAG'}, {'subject': 'matrix MAC88100 IPAG'}, {'subject': 'chondrules MAC88100 IPAG'}, {'subject': 'CAIs MAC88100 IPAG'}, {'subject': 'matrix MIL07700 IPAG'}, {'subject': 'chondrules MIL07700 IPAG'}, {'subject': 'CAIs MIL07700 IPAG'}, {'subject': 'matrix PCA02010 IPAG'}, {'subject': 'chondrules PCA02010 IPAG'}, {'subject': 'CAIs PCA02010 IPAG'}, {'subject': 'matrix PCA02012 IPAG'}, {'subject': 'chondrules PCA02012 IPAG'}, {'subject': 'CAIs PCA02012 IPAG'}, {'subject': 'laboratory measurement'}, {'subject': 'bidirectional reflection'}, {'subject': 'macroscopic'}, {'subject': 'UV'}, {'subject': 'Ultraviolet'}, {'subject': 'Vis'}, {'subject': 'Visible'}, {'subject': 'NIR'}, {'subject': 'Near-Infrared'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'FIR'}, {'subject': 'Far-Infrared'}, {'subject': 'reflectance factor'}]",['23 spectra'],['ASCII']
+10.26302/sshade/experiment_dl_20181107_002,Mn K edge XAS HERFD of synthetic Mn3+­-hydroxylamine at 10K,SSHADE/FAME (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2019-11-15T20:28:33.000Z,2019-11-15T20:28:33.000Z,inist.sshade,mgeg,"laboratory,other compound,Synthetic Mn3+­-hydroxylamine,laboratory measurement,fluorescence emission,None,hard X,hard X-rays","[{'subject': 'laboratory'}, {'subject': 'other compound'}, {'subject': 'Synthetic Mn3+\xad-hydroxylamine'}, {'subject': 'laboratory measurement'}, {'subject': 'fluorescence emission'}, {'subject': 'None'}, {'subject': 'hard X'}, {'subject': 'hard X-rays'}]",['1 spectrum'],['ASCII']
+10.15778/resif.yj2015,"SLIDEQUAKES temporary experiment, Italy (RESIF-SISMOB)",RESIF - Réseau Sismologique et géodésique Français,2017.0,,Dataset,,"Two small antenna installed: 1) on an landslide in the Dolomites (N-Italy), in order to investigate its structure and monitor its motion; 2) on Piton de la Fournaise volcano to investigate the relations between the earthquakes and the small landslides in the caldera.",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2022-03-17T15:28:30.000Z,2022-03-17T15:28:59.000Z,inist.resif,vcob,"Landslide detection,Seismic wave analysis,Local scale modelling","[{'subject': 'Landslide detection'}, {'subject': 'Seismic wave analysis'}, {'subject': 'Local scale modelling'}]","['4 stations, 47Go (miniseed format)']","['Miniseed data', 'stationXML metadata']"
+10.6084/m9.figshare.24202747,Additional file 1 of Obstructive sleep apnea: a major risk factor for COVID-19 encephalopathy?,figshare,2023.0,,Text,Creative Commons Attribution 4.0 International,Additional file 1: Supplemental Table 1. Comparison of patient demographic characteristics between definite OSA group and No OSA group.,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-09-27T03:26:07.000Z,2023-09-27T03:26:07.000Z,figshare.ars,otjm,"Biophysics,Medicine,Cell Biology,Neuroscience,Physiology,FOS: Biological sciences,Pharmacology,Biotechnology,Sociology,FOS: Sociology,Immunology,FOS: Clinical medicine,Cancer,Mental Health,Virology","[{'subject': 'Biophysics'}, {'subject': 'Medicine'}, {'subject': 'Cell Biology'}, {'subject': 'Neuroscience'}, {'subject': 'Physiology'}, {'subject': 'FOS: Biological sciences', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': 'Pharmacology'}, {'subject': 'Biotechnology'}, {'subject': 'Sociology'}, {'subject': 'FOS: Sociology', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': 'Immunology'}, {'subject': 'FOS: Clinical medicine', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': 'Cancer'}, {'subject': 'Mental Health'}, {'subject': 'Virology'}]",['31583 Bytes'],
+10.26302/sshade/bandlist_abs_ch3cn_alpha-ch3cn,Absorption band list of CH3CN in pnatural solid CH3CN (phase alpha),SSHADE/BANDLIST (OSUG Data Center),2021.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","FIR-MIR absorption band list of $CH_3CN$ in natural solid $CH_3CN$ (phase alpha) at 20, 80 and 210 K",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-04-21T07:11:28.000Z,2023-04-21T07:11:29.000Z,inist.sshade,mgeg,"natural CH3CN - phase alpha,Acetonitrile,alpha-Acetonitrile,alpha-acetonitrile (phase II),Acetonitrile,75-05-8,CH3CN,polar molecular solid,molecular solids with polar molecules,nitrile,absorption,FIR,MIR,band frequency,band width,band intensity,transition and vibration modes","[{'subject': 'natural CH3CN - phase alpha', 'subjectScheme': 'name'}, {'subject': 'Acetonitrile', 'subjectScheme': 'name'}, {'subject': 'alpha-Acetonitrile', 'subjectScheme': 'name'}, {'subject': 'alpha-acetonitrile (phase II)', 'subjectScheme': 'name'}, {'subject': 'Acetonitrile', 'subjectScheme': 'IUPAC name'}, {'subject': '75-05-8', 'subjectScheme': 'CAS number'}, {'subject': 'CH3CN', 'subjectScheme': 'formula'}, {'subject': 'polar molecular solid', 'subjectScheme': 'class'}, {'subject': 'molecular solids with polar molecules', 'subjectScheme': 'class'}, {'subject': 'nitrile', 'subjectScheme': 'compound type'}, {'subject': 'absorption', 'subjectScheme': 'var'}, {'subject': 'FIR', 'subjectScheme': 'var'}, {'subject': 'MIR', 'subjectScheme': 'var'}, {'subject': 'band frequency', 'subjectScheme': 'var'}, {'subject': 'band width', 'subjectScheme': 'var'}, {'subject': 'band intensity', 'subjectScheme': 'var'}, {'subject': 'transition and vibration modes', 'subjectScheme': 'var'}]",,['ASCII']
+10.26302/sshade/experiment_dt_20180117_007,V K edge XAS transmission of V metallic foil reference at ambient conditions,SSHADE/FAME (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2019-11-16T07:54:22.000Z,2019-11-16T07:54:22.000Z,inist.sshade,mgeg,"commercial,elemental solid,metallic V,laboratory measurement,transmission,None,hard X,hard X-rays","[{'subject': 'commercial'}, {'subject': 'elemental solid'}, {'subject': 'metallic V'}, {'subject': 'laboratory measurement'}, {'subject': 'transmission'}, {'subject': 'None'}, {'subject': 'hard X'}, {'subject': 'hard X-rays'}]",['1 spectrum'],['ASCII']
+10.26302/sshade/experiment_bs_20130120_004,Mid-IR optical constants of amorpous H2O Ia at 15K and crystalline H2O Ih at 60K,SSHADE/GhoSST (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",Mid-IR optical constants spectrum of amorpous H2O Ia at 15K and crystalline H2O Ih at 60K,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2020-01-03T07:17:17.000Z,2020-01-03T07:17:18.000Z,inist.sshade,mgeg,"laboratory,inorganic molecular solid,H2O amorphous - phase Ia,H2O crystalline - phase Ih,laboratory measurement,transmission,macroscopic,MIR,Mid-Infrared,optical constants","[{'subject': 'laboratory'}, {'subject': 'inorganic molecular solid'}, {'subject': 'H2O amorphous - phase Ia'}, {'subject': 'H2O crystalline - phase Ih'}, {'subject': 'laboratory measurement'}, {'subject': 'transmission'}, {'subject': 'macroscopic'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'optical constants'}]",['2 spectra'],['ASCII']
+10.6084/m9.figshare.c.6851803,Sonometric assessment of cough predicts extubation failure: SonoWean—a proof-of-concept study,figshare,2023.0,,Collection,Creative Commons Attribution 4.0 International,"Abstract Background Extubation failure is associated with increased mortality. Cough ineffectiveness may be associated with extubation failure, but its quantification for patients undergoing weaning from invasive mechanical ventilation (IMV) remains challenging. Methods Patients under IMV for more than 24 h completing a successful spontaneous T-tube breathing trial (SBT) were included. At the end of the SBT, we performed quantitative sonometric assessment of three successive coughing efforts using a sonometer. The mean of the 3-cough volume in decibels was named Sonoscore. Results During a 1-year period, 106 patients were included. Median age was 65 [51–75] years, mainly men (60%). Main reasons for IMV were acute respiratory failure (43%), coma (25%) and shock (17%). Median duration of IMV at enrollment was 4 [3–7] days. Extubation failure occurred in 15 (14%) patients. Baseline characteristics were similar between success and failure extubation groups, except percentage of simple weaning which was lower and MV duration which was longer in extubation failure patients. Sonoscore was significantly lower in patients who failed extubation (58 [52–64] vs. 75 [70–78] dB, P &lt; 0.001). After adjustment on MV duration and comorbidities, Sonoscore remained associated with extubation failure. Sonoscore was predictive of extubation failure with an area under the ROC curve of 0.91 (IC95% [0.83–0.99], P &lt; 0.001). A threshold of Sonoscore &lt; 67.1 dB predicted extubation failure with a sensitivity of 0.93 IC95% [0.70–0.99] and a specificity of 0.82 IC95% [0.73–0.90]. Conclusion Sonometric assessment of cough strength might be helpful to identify patients at risk of extubation failure in patients undergoing IMV.",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-09-26T03:25:48.000Z,2023-09-26T03:25:48.000Z,figshare.ars,otjm,"Medicine,Cell Biology,Physiology,FOS: Biological sciences,Immunology,FOS: Clinical medicine,Infectious Diseases,FOS: Health sciences,Computational Biology","[{'subject': 'Medicine'}, {'subject': 'Cell Biology'}, {'subject': 'Physiology'}, {'subject': 'FOS: Biological sciences', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': 'Immunology'}, {'subject': 'FOS: Clinical medicine', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': 'Infectious Diseases'}, {'subject': 'FOS: Health sciences', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': 'Computational Biology'}]",,
+10.6084/m9.figshare.23575360,Additional file 1 of Decoupling of arsenic and iron release from ferrihydrite suspension under reducing conditions: a biogeochemical model,figshare,2023.0,,Text,Creative Commons Attribution 4.0 International,Additional file 1: Composition of growth media and phylogenetic characterization. The data provided describe the both growth media and the phylogenetic affiliation of the pure strains which were isolated from the FR bacterial community. (DOC 76 KB),mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-06-25T03:11:45.000Z,2023-06-25T03:11:45.000Z,figshare.ars,otjm,"59999 Environmental Sciences not elsewhere classified,FOS: Earth and related environmental sciences,39999 Chemical Sciences not elsewhere classified,FOS: Chemical sciences,Ecology,FOS: Biological sciences,69999 Biological Sciences not elsewhere classified,Cancer","[{'subject': '59999 Environmental Sciences not elsewhere classified', 'schemeUri': 'http://www.abs.gov.au/ausstats/abs@.nsf/0/6BB427AB9696C225CA2574180004463E', 'subjectScheme': 'FOR'}, {'subject': 'FOS: Earth and related environmental sciences', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': '39999 Chemical Sciences not elsewhere classified', 'schemeUri': 'http://www.abs.gov.au/ausstats/abs@.nsf/0/6BB427AB9696C225CA2574180004463E', 'subjectScheme': 'FOR'}, {'subject': 'FOS: Chemical sciences', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': 'Ecology'}, {'subject': 'FOS: Biological sciences', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': '69999 Biological Sciences not elsewhere classified', 'schemeUri': 'http://www.abs.gov.au/ausstats/abs@.nsf/0/6BB427AB9696C225CA2574180004463E', 'subjectScheme': 'FOR'}, {'subject': 'Cancer'}]",['77312 Bytes'],
+10.6084/m9.figshare.24091567,Additional file 2 of Survey of adolescents’ needs and parents’ views on sexual health in juvenile idiopathic arthritis,figshare,2023.0,,Text,Creative Commons Attribution 4.0 International,Supplementary Material 2,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-09-06T17:23:04.000Z,2023-09-06T17:23:04.000Z,figshare.ars,otjm,"Medicine,Science Policy","[{'subject': 'Medicine'}, {'subject': 'Science Policy'}]",['286208 Bytes'],
+10.26302/sshade/experiment_ak_20141111_1,Mid-infrared attenuated total reflectance experiment with K+ exchanged less 2 μm size fraction of montmorillonite (SAz-2) equilibrated with D2O vapor under variable relative humidity,SSHADE/LSD (OSUG Data Center),2019.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2022-11-04T08:19:26.000Z,2022-11-04T08:19:26.000Z,inist.sshade,mgeg,"natural terrestrial,phyllosilicate,K-exchanged montmorillonite SAz-2 size-fraction &lt;2 µm,liquid,D2O 99.9 Sigma-Aldrich,laboratory measurement,ATReflection,macroscopic,MIR,Mid-Infrared,corrected ATR absorbance","[{'subject': 'natural terrestrial'}, {'subject': 'phyllosilicate'}, {'subject': 'K-exchanged montmorillonite SAz-2 size-fraction &lt;2 µm'}, {'subject': 'liquid'}, {'subject': 'D2O 99.9 Sigma-Aldrich'}, {'subject': 'laboratory measurement'}, {'subject': 'ATReflection'}, {'subject': 'macroscopic'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'corrected ATR absorbance'}]",['5 spectra'],['ASCII']
+10.5281/zenodo.10650737,Combining Loop Shuffling and Code Polymorphism for Enhanced AES Side-Channel Security,Zenodo,2024.0,en,Dataset,Creative Commons Attribution No Derivatives 4.0 International,"This repository contains the datasets used for deep learning for our paper ""Combining Loop Shuffling and Code Polymorphism for Enhanced AES Side-Channel Security"", published at COSADE 2024.
+
+It contains:- A dataset of traces measured on a STM32F7. Detailed experimental setup is available in the paper. The traces measured are long enough to contain the full first round of the AES.- A dataset of simulated traces. Simulated traces output 2 samples for each instruction executed: one sample consisting of the sum of the Hamming weights of the input registers, and one sample consisting of (the sum of) the Hamming weight(s) of the output register(s). The traces contain all rounds of the AES.
+
+Note that the plaintexts file is different in both dataset.
+
+**IMPORTANT NOTE:**This dataset stems from a serie of experiments carried on a particular implementation of AES, with particular configurations of the countermeasures. We stress that other security levels (lower or higher) can be reached with the considered countermeasures depending on the platform, the implementation, the configuration of the countermeasures etc. In particular, the code polymorphism countermeasure is highly configurable, and this dataset is limited to the configuration described in the paper.",api,True,findable,0.0,0.0,0.0,0.0,0.0,2024-02-12T14:54:51.000Z,2024-02-12T14:54:51.000Z,cern.zenodo,cern,,,,
+10.5281/zenodo.10157907,X-ray diffraction images for Hen Egg White Lysozyme (HEWL) co-crystallized with 10mM TbXo4-SO3 - PDB ID: 8POB,Zenodo,2023.0,,Dataset,Creative Commons Attribution 4.0 International,"Xray diffraction images for HEWL structure co-crystallized with 10mM TbXo4-SO3. Dataset Collected at SOLEIL-Proxima 1 (PX1) beamline.For experimental details, see XDS.INP file (input file for XDS program).",api,True,findable,0.0,0.0,0.0,0.0,0.0,2024-01-18T23:29:21.000Z,2024-01-18T23:29:22.000Z,cern.zenodo,cern,,,,
+10.15778/resif.zh2016,POSA experiment,RESIF - Réseau Sismologique et géodésique Français,2013.0,en,Dataset,"Open Access,Creative Commons Attribution 4.0 International","The POSA project, centred on the Mediterranean region, adress the question of on shore risk management upstream to the operations of counter mining in marine domain. We have thus lean on campaigns of measurements during operations of counter mining of explosive devices of the Second World War of diverse powers and in diverse environments. Two broad band stations were installed for the project duration around bay of Toulon (France) were most of the explosions are performed.",mds,True,findable,0.0,0.0,0.0,3.0,0.0,2018-04-04T13:29:01.000Z,2018-04-04T13:29:01.000Z,inist.resif,vcob,"Counter mining,marine explosion,Risk assesment,seismic waves propagation,seismic noise","[{'subject': 'Counter mining'}, {'subject': 'marine explosion'}, {'subject': 'Risk assesment'}, {'subject': 'seismic waves propagation'}, {'subject': 'seismic noise'}]","['2 stations,25 Gb per year']","['Miniseed data', 'stationXML metadata']"
+10.26302/sshade/bandlist_raman_beta_k2caco3-2,Raman bandlist of synthetic beta-K2Ca(CO3)2 (Fairchildite),SSHADE/BANDLIST (OSUG Data Center),2023.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",MIR-FIR Raman bandlist of synthetic $\beta-K_2Ca(CO_3)_2$ (Fairchildite) at 295K,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-09-10T17:21:27.000Z,2023-09-10T17:21:28.000Z,inist.sshade,mgeg,"$K_2Ca(CO_3)_2$ - phase beta,Potassium(1+) cation,Calcium cation,Carbonate anion,beta Dipotassium calcium carbonate,$\beta-K_2Ca(CO_3)_2$,Potassium cation,Calcium(2+) cation,24203-36-9,14127-61-8,K+,Ca2+,(CO3)2-,K2Ca(CO3)2,normal salt,normal salts,carbonate,Raman scattering,FIR,MIR,band frequency,band width,band intensity,transition and vibration modes","[{'subject': '$K_2Ca(CO_3)_2$ - phase beta', 'subjectScheme': 'name'}, {'subject': 'Potassium(1+) cation', 'subjectScheme': 'name'}, {'subject': 'Calcium cation', 'subjectScheme': 'name'}, {'subject': 'Carbonate anion', 'subjectScheme': 'name'}, {'subject': 'beta Dipotassium calcium carbonate', 'subjectScheme': 'name'}, {'subject': '$\\beta-K_2Ca(CO_3)_2$', 'subjectScheme': 'name'}, {'subject': 'Potassium cation', 'subjectScheme': 'IUPAC name'}, {'subject': 'Calcium(2+) cation', 'subjectScheme': 'IUPAC name'}, {'subject': '24203-36-9', 'subjectScheme': 'CAS number'}, {'subject': '14127-61-8', 'subjectScheme': 'CAS number'}, {'subject': 'K+', 'subjectScheme': 'formula'}, {'subject': 'Ca2+', 'subjectScheme': 'formula'}, {'subject': '(CO3)2-', 'subjectScheme': 'formula'}, {'subject': 'K2Ca(CO3)2', 'subjectScheme': 'formula'}, {'subject': 'normal salt', 'subjectScheme': 'class'}, {'subject': 'normal salts', 'subjectScheme': 'class'}, {'subject': 'carbonate', 'subjectScheme': 'compound type'}, {'subject': 'Raman scattering', 'subjectScheme': 'variables'}, {'subject': 'FIR', 'subjectScheme': 'variables'}, {'subject': 'MIR', 'subjectScheme': 'variables'}, {'subject': 'band frequency', 'subjectScheme': 'variables'}, {'subject': 'band width', 'subjectScheme': 'variables'}, {'subject': 'band intensity', 'subjectScheme': 'variables'}, {'subject': 'transition and vibration modes', 'subjectScheme': 'variables'}]",,['ASCII']
+10.26302/sshade/experiment_rc_20200618_000,"VIS reflectance spectra collected during electron irradiation experiments of salty fine-grained ice particles (spherical, 5 µm average diameter) prepared by freezing solutions of NaCl with different concentrations.",SSHADE/BYPASS (OSUG Data Center),2023.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.","Spherical salty ice particles are produced by spraying droplets of NaCl solutions into liquid nitrogen with the SPIPA-A setup and 9mm-thick samples are produced from this material. The samples are then introduced into the MEFISTO chamber, placed on a liquid nitrogen cooling plate, and the chamber is evacuated to high vacuum. The samples can then be bombarded with energetic electrons at different energies and fluxes and VIS hyperspectral images are collected.",mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-07-31T13:28:50.000Z,2023-07-31T13:28:50.000Z,inist.sshade,mgeg,"laboratory measurement,biconical reflection,imaging,Vis,Visible,reflectance factor,water ice,NaCl hydrate,laboratory,inorganic molecular solid,chloride","[{'subject': 'laboratory measurement', 'subjectScheme': 'main'}, {'subject': 'biconical reflection', 'subjectScheme': 'main'}, {'subject': 'imaging', 'subjectScheme': 'main'}, {'subject': 'Vis', 'subjectScheme': 'variables'}, {'subject': 'Visible', 'subjectScheme': 'variables'}, {'subject': 'reflectance factor', 'subjectScheme': 'variables'}, {'subject': 'water ice', 'subjectScheme': 'name'}, {'subject': 'NaCl hydrate', 'subjectScheme': 'name'}, {'subject': 'laboratory', 'subjectScheme': 'origin'}, {'subject': 'inorganic molecular solid', 'subjectScheme': 'compound type'}, {'subject': 'chloride', 'subjectScheme': 'compound type'}]",['14 spectra'],['ASCII']
+10.5281/zenodo.10653154,tlibs,Zenodo,2024.0,,Software,GNU General Public License v3.0 only,"Tlibs version 2, a physical-mathematical C++ template library.",api,True,findable,0.0,0.0,0.0,1.0,0.0,2024-02-13T08:36:41.000Z,2024-02-13T08:36:41.000Z,cern.zenodo,cern,,,,
+10.26302/sshade/experiment_pa_20180702_001,Mo K edge XAS transmission of molybdenum dioxyde MoO2,SSHADE/FAME (OSUG Data Center),2019.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2019-12-16T15:01:57.000Z,2019-12-16T15:01:58.000Z,inist.sshade,mgeg,"solid,commercial,non-oxide ceramic,BN powder,oxide,molybdenum dioxyde MoO2,laboratory measurement,transmission,None,hard X,hard X-rays","[{'subject': 'solid'}, {'subject': 'commercial'}, {'subject': 'non-oxide ceramic'}, {'subject': 'BN powder'}, {'subject': 'oxide'}, {'subject': 'molybdenum dioxyde MoO2'}, {'subject': 'laboratory measurement'}, {'subject': 'transmission'}, {'subject': 'None'}, {'subject': 'hard X'}, {'subject': 'hard X-rays'}]",['1 spectrum'],['ASCII']
+10.26302/sshade/experiment_dt_20180313_001,Mn K edge XAS transmission of Mn metallic foil reference at ambient conditions,SSHADE/FAME (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2019-11-16T07:53:42.000Z,2019-11-16T07:53:43.000Z,inist.sshade,mgeg,"commercial,elemental solid,metallic Mn,laboratory measurement,transmission,None,hard X,hard X-rays","[{'subject': 'commercial'}, {'subject': 'elemental solid'}, {'subject': 'metallic Mn'}, {'subject': 'laboratory measurement'}, {'subject': 'transmission'}, {'subject': 'None'}, {'subject': 'hard X'}, {'subject': 'hard X-rays'}]",['1 spectrum'],['ASCII']
+10.6084/m9.figshare.24196813,Additional file 1 of Sonometric assessment of cough predicts extubation failure: SonoWean—a proof-of-concept study,figshare,2023.0,,Text,Creative Commons Attribution 4.0 International,"Additional file 1. Supplemental Fig 1: Description of the Pulsar Model 14® Sound Level Meter and method for measurement. The Model 14 is a general purpose digital sound level meter which meets the full requirements of IEC 61672 to Class 2. Before each inclusion the Sound Level Meter was calibrated acoustically using an external reference, i.e the Sound Level Calibrator Model 106, which is placed over the microphone. The calibrator generates a stabilized Sound Pressure Level of 94dB (+- 0.3dB) at a frequency of 1 kHz. Using a Low range (Low = 35dB to 100dB), maximum sound level was measured pressing the MAX HOLD button for at least ½ second and was ultimately noticed. A level of sound in decibels (L) is defined as ten times the base-10 logarithm of the ratio between two power-related quantities I (i.e cough-volume related sound) and Io (i.e the human hearing threshold) as follows: L = 10 * Log 10 (I/ Io). Thus, an apparent mild increase from 73 to 76 dB in sound level results in multiplying acoustic energy by a factor two.",mds,True,findable,0.0,0.0,20.0,0.0,0.0,2023-09-26T03:25:47.000Z,2023-09-26T03:25:47.000Z,figshare.ars,otjm,"Medicine,Cell Biology,Physiology,FOS: Biological sciences,Immunology,FOS: Clinical medicine,Infectious Diseases,FOS: Health sciences,Computational Biology","[{'subject': 'Medicine'}, {'subject': 'Cell Biology'}, {'subject': 'Physiology'}, {'subject': 'FOS: Biological sciences', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': 'Immunology'}, {'subject': 'FOS: Clinical medicine', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': 'Infectious Diseases'}, {'subject': 'FOS: Health sciences', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': 'Computational Biology'}]",['117717 Bytes'],
+10.6084/m9.figshare.24091564,Additional file 1 of Survey of adolescents’ needs and parents’ views on sexual health in juvenile idiopathic arthritis,figshare,2023.0,,Text,Creative Commons Attribution 4.0 International,Supplementary Material 1,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-09-06T17:23:03.000Z,2023-09-06T17:23:03.000Z,figshare.ars,otjm,"Medicine,Science Policy","[{'subject': 'Medicine'}, {'subject': 'Science Policy'}]",['309248 Bytes'],
+10.26302/sshade/bandlist_abs_co_alpha-co,Absorption band list of CO in natural solid CO (phase alpha),SSHADE/BANDLIST (OSUG Data Center),2021.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",VUV-NIR-MIR-FIR absorption band list of the isotopes of $CO$ in natural solid $\alpha-CO$,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2023-04-21T07:11:08.000Z,2023-04-21T07:11:09.000Z,inist.sshade,mgeg,"natural CO - phase alpha,Carbon monoxide,alpha Carbon Monoxide,$\alpha-CO$,Carbon monoxide,630-08-0,CO,polar molecular solid,molecular solids with polar molecules,inorganic molecular solid,absorption,VUV,NIR,MIR,FIR,band frequency,band width,band intensity,transition and vibration modes","[{'subject': 'natural CO - phase alpha', 'subjectScheme': 'name'}, {'subject': 'Carbon monoxide', 'subjectScheme': 'name'}, {'subject': 'alpha Carbon Monoxide', 'subjectScheme': 'name'}, {'subject': '$\\alpha-CO$', 'subjectScheme': 'name'}, {'subject': 'Carbon monoxide', 'subjectScheme': 'IUPAC name'}, {'subject': '630-08-0', 'subjectScheme': 'CAS number'}, {'subject': 'CO', 'subjectScheme': 'formula'}, {'subject': 'polar molecular solid', 'subjectScheme': 'class'}, {'subject': 'molecular solids with polar molecules', 'subjectScheme': 'class'}, {'subject': 'inorganic molecular solid', 'subjectScheme': 'compound type'}, {'subject': 'absorption', 'subjectScheme': 'var'}, {'subject': 'VUV', 'subjectScheme': 'var'}, {'subject': 'NIR', 'subjectScheme': 'var'}, {'subject': 'MIR', 'subjectScheme': 'var'}, {'subject': 'FIR', 'subjectScheme': 'var'}, {'subject': 'band frequency', 'subjectScheme': 'var'}, {'subject': 'band width', 'subjectScheme': 'var'}, {'subject': 'band intensity', 'subjectScheme': 'var'}, {'subject': 'transition and vibration modes', 'subjectScheme': 'var'}]",,['ASCII']
+10.26302/sshade/experiment_ak_20141112_1,Mid-infrared attenuated total reflectance experiment with K+ exchanged less 2 μm size fraction of synthetic saponite equilibrated with D2O vapor under variable relative humidity,SSHADE/LSD (OSUG Data Center),2018.0,en,Dataset,"Any use of downloaded SSHADE data in a scientific or technical paper or a presentation is free but you should cite both SSHADE and the used data in the text ( 'first author' et al., year) with its full reference (with its DOI) in the main reference section of the paper (or in a special 'data citation' section) and, when available, the original paper(s) presenting the data.",,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2022-11-04T08:14:20.000Z,2022-11-04T08:14:21.000Z,inist.sshade,mgeg,"natural terrestrial,phyllosilicate,K-exchanged saponite SAP size-fraction &lt;2 µm,liquid,D2O 99.9 Sigma-Aldrich,laboratory measurement,ATReflection,macroscopic,MIR,Mid-Infrared,corrected ATR absorbance","[{'subject': 'natural terrestrial'}, {'subject': 'phyllosilicate'}, {'subject': 'K-exchanged saponite SAP size-fraction &lt;2 µm'}, {'subject': 'liquid'}, {'subject': 'D2O 99.9 Sigma-Aldrich'}, {'subject': 'laboratory measurement'}, {'subject': 'ATReflection'}, {'subject': 'macroscopic'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'corrected ATR absorbance'}]",['5 spectra'],['ASCII']
+10.15778/resif.6b2021,"DEEP_TRIGGER temporary experiment in the subduction zone Peru/Chile, Peru (RESIF-SISMOB)",RESIF - Réseau Sismologique et géodésique Français,2022.0,,Dataset,,"Preparation of subduction Earthquakes : Slow, Deep, Large-scale trigger. DeepTrigger is a project funded by the European Research Council. The aim of the project is to study the preparation of subduction earthquakes in the Chile/Peru subduction area. The seismological network deployed in Peru (6B network) is composed of 24 stations (13 broad-band velocimeters (Nanometrics T120-QA) and 11 medium-band velocimeter (Nanometrics TC20-PH). Those 24 stations will be deployed during ~3 years in southern Peru (network code 6B) from March 2022 to March 2025. The targeted area in South Peru (13°S-17°S) has been partly affected by the 2001 Mw8.4 Arequipa earthquake, and has been loaded at both extremities by the Mw8 Pisco earthquake in 2007 in the area of the Nazca ridge, and by the 2014 Mw 8.3 Iquique earthquake in North Chile. It is an area characterized by important intraslab seismicity. The megathrust is characterized by lateral variations of coupling, notably the Nazca Ridge is an intersegment area, characterized by a low coupling value, and therefore prone to host slow slip events. This area appears as an excellent target to hunt for deep – shallow interactions, large-scale transients (the effect of 2014 Iquique earthquake should be investigated), and slow slip events in low coupling areas, notably in the area of the Nazca ridge. The installed seismological network will provide key data to investigate these questions. Precise catalogues of seismicity will be generated, in which swarm, repeaters and clusters will be identified and analysed. LFEs and tremors will also be systematically scanned, catalogued and analysed.",fabrica,True,findable,0.0,0.0,0.0,0.0,0.0,2023-03-30T15:00:22.000Z,2023-03-30T15:00:57.000Z,inist.resif,vcob,"Seismology,Subduction,Earthquake,Peru,South America","[{'subject': 'Seismology'}, {'subject': 'Subduction'}, {'subject': 'Earthquake'}, {'subject': 'Peru'}, {'subject': 'South America'}]","['25 stations, 189Go (miniseed format)']","['Miniseed data', 'stationXML metadata']"
+10.15778/resif.xw2019,Noise monitoring of the groundwater in Albion area : ALBION2 (RESIF-SISMOB),RESIF - Réseau Sismologique et géodésique Français,2020.0,,Dataset,,A set of 20 broadband seismic stations operating for nearly two years in the Plateau d’Albion area. The dataset is formed of continuous seismic recordings @100Hz of sampling frequency.,mds,True,findable,0.0,0.0,0.0,0.0,0.0,2021-01-11T09:51:19.000Z,2021-01-11T09:51:45.000Z,inist.resif,vcob,"Seismic noise,Boadband seismology,Water monitoring","[{'subject': 'Seismic noise'}, {'subject': 'Boadband seismology'}, {'subject': 'Water monitoring'}]","['19 stations, 292Go (miniseed format)']","['Miniseed data', 'stationXML metadata']"