Newer
Older
doi,title,publisher,publicationYear,language,resourceTypeGeneral,rights,description,source,isActive,state,viewCount,downloadCount,referenceCount,citationCount,versionCount,created,registered,client,provider,subject,subject_raw,sizes,formats,relation_nbInstances,relation_nbCitation,all_relations,traveled_dois
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
149
150
151
152
153
154
155
156
157
158
159
160
161
162
163
164
165
166
167
168
169
170
171
172
173
174
175
176
177
178
179
180
181
182
183
184
185
186
187
188
189
190
191
192
193
194
195
196
197
198
199
200
201
202
203
204
205
206
207
208
209
210
211
212
213
214
215
216
217
218
219
220
221
222
223
224
225
226
227
228
229
230
231
232
233
234
235
236
237
238
239
240
241
242
243
244
245
246
247
248
249
250
251
252
253
254
255
256
257
258
259
260
261
262
263
264
265
266
267
268
269
270
271
272
273
274
275
276
277
278
279
280
281
282
283
284
285
286
287
288
289
290
291
292
293
294
295
296
297
298
299
300
301
302
303
304
305
306
307
308
309
310
311
312
313
314
315
316
317
318
319
320
321
322
323
324
325
326
327
328
329
330
331
332
333
334
335
336
337
338
339
340
341
342
343
344
345
346
347
348
349
350
351
352
353
354
355
356
357
358
359
360
361
362
363
364
365
366
367
368
369
370
371
372
373
374
375
376
377
378
379
380
381
382
383
384
385
386
387
388
389
390
391
392
393
394
395
396
397
398
399
400
401
402
403
404
405
406
407
408
409
410
411
412
413
414
415
416
417
418
419
420
421
422
423
424
425
426
427
428
429
430
431
432
433
434
435
436
437
438
439
440
441
442
443
444
445
446
447
448
449
450
451
452
453
454
455
456
457
458
459
460
461
462
463
464
465
466
467
468
469
470
471
472
473
474
475
476
477
478
479
480
481
482
483
484
485
486
487
488
489
490
491
492
493
494
495
496
497
498
499
500
501
502
503
504
505
506
507
508
509
510
511
512
513
514
515
516
517
518
519
520
521
522
523
524
525
526
527
528
529
530
531
532
533
534
535
536
537
538
539
540
541
542
543
544
545
546
547
548
549
550
551
552
553
554
555
556
557
558
559
560
561
562
563
564
565
566
567
568
569
570
571
572
573
574
575
576
577
578
579
580
581
582
583
584
585
586
587
588
589
590
591
592
593
594
595
596
597
598
599
600
601
602
603
604
605
606
607
608
609
610
611
612
613
614
615
616
617
618
619
620
621
622
623
624
625
626
627
628
629
630
631
632
633
634
635
636
637
638
639
640
641
642
643
644
645
646
647
648
649
650
651
652
653
654
655
656
657
658
659
660
661
662
663
664
665
666
667
668
669
670
671
672
673
674
675
676
677
678
679
680
681
682
683
684
685
686
687
688
689
690
691
692
693
694
695
696
697
698
699
700
701
702
703
704
705
706
707
708
709
710
711
712
713
714
715
716
717
718
719
720
721
722
723
724
725
726
727
728
729
730
731
732
733
734
735
736
737
738
739
740
741
742
743
744
745
746
747
748
749
750
751
752
753
754
755
756
757
758
759
760
761
762
763
764
765
766
767
768
769
770
771
772
773
774
775
776
777
778
779
780
781
782
783
784
785
786
787
788
789
790
791
792
793
794
795
796
797
798
799
800
801
802
803
804
805
806
807
808
809
810
811
812
813
814
815
816
817
818
819
820
821
822
823
824
825
826
827
828
829
830
831
832
833
834
835
836
837
838
839
840
841
842
843
844
845
846
847
848
849
850
851
852
853
854
855
856
857
858
859
860
861
862
863
864
865
866
867
868
869
870
871
872
873
874
875
876
877
878
879
880
881
882
883
884
885
886
887
888
889
890
891
892
893
894
895
896
897
898
899
900
901
902
903
904
905
906
907
908
909
910
911
912
913
914
915
916
917
918
919
920
921
922
923
924
925
926
927
928
929
930
931
932
933
934
935
936
937
938
939
940
941
942
943
944
945
946
947
948
949
950
951
952
953
954
955
956
957
958
959
960
961
962
963
964
965
966
967
968
969
970
971
972
973
974
975
976
977
978
979
980
981
982
983
984
985
986
987
988
989
990
991
992
993
994
995
996
997
998
999
1000
10.17178/amma-catch.cl.rain_o,"Precipitation dataset (5 minutes rainfall), 30 long-term stations over the upper Oueme watershed (14 000 km2), Benin","IRD, CNRS-INSU, OSUG, OMP, OREME",1999,en,Dataset,"Creative Commons Attribution 4.0 International,Data access and use are ruled by the AMMA-CATCH data policy.,For any publication using AMMA-CATCH data, authors are asked to:
Mandatory: cite the reference article and the DOI of the observatory
(1) Galle et al. (2018). AMMA-CATCH a Critical Zone Observatory in West Africa Monitoring a Region in Transition. Vadose Zone Journal, 17 (1), 18006.
(2) AMMA-CATCH (1990). AMMA-CATCH : a hydrological, meteorological and ecological observatory on West Africa. IRD, CNRS-INSU, OSUG, OMP, OREME. doi:10.17178/AMMA-CATCH.all
Optional: cite the DOI of each dataset used.
Co-authorship: depending on the contribution of the data to the scientific results obtained, the authors should either propose co-authorship to the data providers or at least acknowledge their contribution.","Documentation of rainfall in the soudanian zone. The aim is to characterize the temporal and spatial variability of rainfall at meso-scale, with a good resolution of the convective scale patterns. Data is used in modelling and assimilation activities, process studies as well as for validation of satellite products.",mds,True,findable,0,0,1,0,0,2018-03-16T15:37:15.000Z,2018-03-16T15:37:16.000Z,inist.osug,jbru,"Rainfall, precipitation, tropical convection,Sudanian climate,Precipitation Amount (previous hour),Precipitation Amount (previous 5 minutes),Precipitation Amount (previous 24 hours)","[{'subject': 'Rainfall, precipitation, tropical convection', 'subjectScheme': 'main'}, {'subject': 'Sudanian climate', 'subjectScheme': 'main'}, {'subject': 'Precipitation Amount (previous hour)', 'subjectScheme': 'var'}, {'subject': 'Precipitation Amount (previous 5 minutes)', 'subjectScheme': 'var'}, {'subject': 'Precipitation Amount (previous 24 hours)', 'subjectScheme': 'var'}]",,"['CSV', 'NETCDF', 'O&M 1.0']",,,"['Cites', 'IsPartOf', 'IsPartOf']",
10.5281/zenodo.888976,MB2017: Artificial spiking neural data with ground truth,Zenodo,2017,,Dataset,"Creative Commons Attribution 4.0 International,Open Access","This dataset comprises simulated extracellular spiking neural signals, for which the activity of the active neurons is known. These data can thus be used to test spike sorting algorithms.
This dataset has been generated for the study reported in:
Bernert M, Yvert B (2018) An attention-based spiking neural network for unsupervised spike-sorting. International Journal of Neural Systems, https://doi.org/10.1142/S0129065718500594
Please cite this paper as a reference.",mds,True,findable,0,0,0,0,0,2019-01-03T14:33:40.000Z,2019-01-03T14:33:41.000Z,cern.zenodo,cern,"microelectrode, action potentials, spike sorting, extracellular neural activity","[{'subject': 'microelectrode, action potentials, spike sorting, extracellular neural activity'}]",,,,,"['HasVersion', 'IsPartOf', 'IsPartOf']","[['IsVersionOf', '10.5281/zenodo.888976']]"
10.26302/sshade/bandlist_abs_so2_so2-i,Absorption band list of SO2 in natural solid SO2 (phase I),SSHADE/BANDLIST (OSUG Data Center),2021,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 absorption band list of $SO_2$ in natural solid $SO_2$ (phase I) at 20, 90 and 125 K",mds,True,findable,0,0,0,0,0,2023-04-21T07:12:29.000Z,2023-04-21T07:12:30.000Z,inist.sshade,mgeg,"natural SO2 - phase I,Sulfur dioxide,Sulfur dioxide phase I,Phase I,Sulfur dioxide,7446-09-5,SO2,polar molecular solid,molecular solids with polar molecules,inorganic molecular solid,absorption,FIR,MIR,NIR,band frequency,band width,band intensity,transition and vibration modes","[{'subject': 'natural SO2 - phase I', 'subjectScheme': 'name'}, {'subject': 'Sulfur dioxide', 'subjectScheme': 'name'}, {'subject': 'Sulfur dioxide phase I', 'subjectScheme': 'name'}, {'subject': 'Phase I', 'subjectScheme': 'name'}, {'subject': 'Sulfur dioxide', 'subjectScheme': 'IUPAC name'}, {'subject': '7446-09-5', 'subjectScheme': 'CAS number'}, {'subject': 'SO2', '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': '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'],,,"['IsPartOf', 'IsPartOf', 'IsDerivedFrom', 'Cites', 'IsSourceOf', 'Cites', 'IsSourceOf', 'Cites', 'IsDerivedFrom', 'Cites', 'IsSourceOf', 'Cites', 'IsSourceOf', 'Cites', 'IsSourceOf', 'Cites', 'IsDerivedFrom', 'Cites', 'IsSourceOf', 'Cites', 'IsSourceOf', 'Cites', 'IsDerivedFrom', 'Cites', 'IsSourceOf', 'Cites', 'IsSourceOf', 'Cites', 'IsDerivedFrom', 'Cites', 'IsSourceOf', 'Cites', 'IsSourceOf', 'Cites', 'IsDerivedFrom', 'Cites', 'IsSourceOf', 'Cites', 'IsSourceOf', 'Cites']",
10.26302/sshade/bandlist_raman_ch3cn_alpha-ch3cn,Raman band list of CH3CN in natural solid CH3CN (phase alpha),SSHADE/BANDLIST (OSUG Data Center),2021,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 band list of $CH_3CN$ in natural solid $CH_3CN$ (phase alpha) at 80 K,mds,True,findable,0,0,0,0,0,2023-04-21T07:13:20.000Z,2023-04-21T07:13:21.000Z,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,Raman scattering,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': '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'],,,"['IsPartOf', 'IsPartOf', 'IsDerivedFrom', 'Cites', 'IsSourceOf', 'Cites', 'IsSourceOf', 'Cites', 'IsDerivedFrom', 'Cites', 'IsSourceOf', 'Cites', 'IsSourceOf', 'Cites']",
10.5281/zenodo.1475905,Third Harmonic Generation Images Of The Lacuno-Canalicular Network In Bone Femoral Diaphysis Of Mice From The Bionm1 Project (Space Flight),Zenodo,2018,,Dataset,"Creative Commons Attribution 4.0,Open Access","Data set for 11 samples in 3 groups of Control, Space Flight and Synchro (ground control with space flight housing and feeding conditions). Contains THG images in tif format of 2D mosaic of selected samples and 3D stacks in selected anatomical regions of interest. See readme file for more information.",mds,True,findable,0,0,0,0,0,2018-10-31T16:24:03.000Z,2018-10-31T16:24:04.000Z,cern.zenodo,cern,"THG, bone, osteocyte, LCN, lacunae, canaliculi, space flight","[{'subject': 'THG, bone, osteocyte, LCN, lacunae, canaliculi, space flight'}]",,,,,['HasVersion'],"[['IsVersionOf', '10.5281/zenodo.1475905']]"
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,,Text,Creative Commons Attribution 4.0 International,Additional file 1. Location of the 20 pediatric rheumatology centers (using Google Maps).,mds,True,findable,0,0,0,0,0,2023-04-13T15:53:31.000Z,2023-04-13T15:53:32.000Z,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'],,,,"['IsSupplementTo', 'IsIdenticalTo']","[['IsIdenticalTo', '10.6084/m9.figshare.22617740']]"
10.5281/zenodo.5511679,JASPAR TFBS LOLA databases - Part 2,Zenodo,2022,,Dataset,"Creative Commons Attribution 4.0 International,Open Access","This repository contains the second part of the JASPAR 2022 LOLA databases used by the JASPAR TFBS enrichment tool. We provide the LOLA databases for the human (hg38) JASPAR 2022 TFBS sets as compressed directories containing a set of .RDS R objects. Due to file sizes, we had to split the repository into two different parts. Part 1 of the repository containing the rest of databases can be found here.",mds,True,findable,0,0,0,0,0,2022-07-25T12:25:34.000Z,2022-07-25T12:25:35.000Z,cern.zenodo,cern,,,,,,,"['HasVersion', 'HasVersion', 'HasVersion']","[['IsVersionOf', '10.5281/zenodo.5511679']]"
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,,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,0,0,0,0,0,2023-11-02T05:00:07.000Z,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_c2n2-c2n2-i,Raman band list of C2N2 in natural solid C2N2 (phase I),SSHADE/BANDLIST (OSUG Data Center),2021,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 $C_2N_2$ in natural solid $C_2N_2$ (phase I) beetween 20 and 120 K,mds,True,findable,0,0,0,0,0,2023-04-21T07:12:57.000Z,2023-04-21T07:12:58.000Z,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,Raman scattering,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': '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'],,,"['IsPartOf', 'IsPartOf', 'IsDerivedFrom', 'Cites', 'IsSourceOf', 'Cites', 'IsSourceOf', 'Cites', 'IsDerivedFrom', 'Cites', 'IsSourceOf', 'Cites', 'IsSourceOf', 'Cites']",
10.5281/zenodo.4729757,Prevalence of nonsensical algorithmically generated papers in the scientific literature,Zenodo,2021,en,Software,"Creative Commons Attribution 4.0 International,Open Access",research integrity<br> publishing industry<br> misconduct<br> retraction<br> computer-generated papers<br> SCIgen<br> nonsense detection<br> citation manipulation,mds,True,findable,0,0,0,0,0,2021-05-19T14:11:14.000Z,2021-05-19T14:11:15.000Z,cern.zenodo,cern,"computer-generated papers,SCIgen,nonsense detection,research integrity,misconduct,publishing industry","[{'subject': 'computer-generated papers'}, {'subject': 'SCIgen'}, {'subject': 'nonsense detection'}, {'subject': 'research integrity'}, {'subject': 'misconduct'}, {'subject': 'publishing industry'}]",,,,,"['IsSupplementTo', 'HasVersion']","[['IsVersionOf', '10.5281/zenodo.4729757']]"
10.6084/m9.figshare.c.7081935,Healthcare-associated infections in patients with severe COVID-19 supported with extracorporeal membrane oxygenation: a nationwide cohort study,figshare,2024,,Collection,Creative Commons Attribution 4.0 International,"Abstract Background Both critically ill patients with coronavirus disease 2019 (COVID-19) and patients receiving extracorporeal membrane oxygenation (ECMO) support exhibit a high incidence of healthcare-associated infections (HAI). However, data on incidence, microbiology, resistance patterns, and the impact of HAI on outcomes in patients receiving ECMO for severe COVID-19 remain limited. We aimed to report HAI incidence and microbiology in patients receiving ECMO for severe COVID-19 and to evaluate the impact of ECMO-associated infections (ECMO-AI) on in-hospital mortality. Methods For this study, we analyzed data from 701 patients included in the ECMOSARS registry which included COVID-19 patients supported by ECMO in France. Results Among 602 analyzed patients for whom HAI and hospital mortality data were available, 214 (36%) had ECMO-AI, resulting in an incidence rate of 27 ECMO-AI per 1000 ECMO days at risk. Of these, 154 patients had bloodstream infection (BSI) and 117 patients had ventilator-associated pneumonia (VAP). The responsible microorganisms were Enterobacteriaceae (34% for BSI and 48% for VAP), Enterococcus species (25% and 6%, respectively) and non-fermenting Gram-negative bacilli (13% and 20%, respectively). Fungal infections were also observed (10% for BSI and 3% for VAP), as were multidrug-resistant organisms (21% and 15%, respectively). Using a Cox multistate model, ECMO-AI were not found associated with hospital death (HR = 1.00 95% CI [0.79–1.26], p = 0.986). Conclusions In a nationwide cohort of COVID-19 patients receiving ECMO support, we observed a high incidence of ECMO-AI. ECMO-AI were not found associated with hospital death. Trial registration number NCT04397588 (May 21, 2020).",mds,True,findable,0,0,0,0,0,2024-02-20T04:42:21.000Z,2024-02-20T04:42:21.000Z,figshare.ars,otjm,"Microbiology,FOS: Biological sciences,Immunology,FOS: Clinical medicine,Cancer,Science Policy,Infectious Diseases,FOS: Health sciences,Virology","[{'subject': 'Microbiology'}, {'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'}, {'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'}]",,,,,['IsIdenticalTo'],"[['IsIdenticalTo', '10.6084/m9.figshare.c.7081935']]"
10.5281/zenodo.4888803,"Code repository for 'Jarzynski equality and Crooks relation for local models of air-sea interaction', a ESD paper",Zenodo,2021,,Software,"Creative Commons Attribution 4.0 International,Open Access","This repository contains the publicly-redistributable code used in the production of ``Jarzynski equality and Crooks relation for local models of air-sea interaction'' a paper by A. Wirth, and F. Lemarié published in Earth System Dynamics. The fortran code corresponds to the 1D2C model described in section 2.1 of the paper",mds,True,findable,0,0,0,0,0,2021-06-01T07:07:15.000Z,2021-06-01T07:07:16.000Z,cern.zenodo,cern,,,,,,,"['IsCitedBy', 'HasVersion']","[['IsVersionOf', '10.5281/zenodo.4888803']]"
10.6084/m9.figshare.14450784,Additional file 2 of Rare deleterious mutations of HNRNP genes result in shared neurodevelopmental disorders,figshare,2021,,Text,Creative Commons Attribution 4.0 International,"Additional file 2: Supplementary Figures S1-S5. Fig. S1. Dendrogram of hnRNPs based on multiple sequence alignment of canonical amino acid sequences. Colors match those seen in Fig. 2. NDD hnRNPs are shown in black boxes. Fig. S2. Pathogenicity assessment of variation in hnRNPs. A) Gene Variation Intolerance Ranking (GeVIR), loss-of-function observed/expected upper bound fraction (LOEUF), and Variation Intolerant Region Loss-of-Function (VIRLoF) percentiles. Average LOEUF percentile is significantly higher for NDD HNRNPs (n = 13) compared to other HNRNPs (n = 15). B) Average fold change for GeVIR, LEOUF, and VIRLoF for autosomal dominant (AD) and autosomal recessive (AR) variants. Average LEOUF fold change for AD mutations is significantly higher for NDD HNRNPs compared to other HNRNPs, with the AD VIRLoF fold change trending in the same direction. The AR LEOUF fold change is trending towards being significantly higher among other HNRNPs compared to NDD HNRNPs. One-way t-test. * p < 0.05. Fig. S3. Expression of HNRNPs among adult tissues and the developing human cortex. A) Heatmap of all HNRNP expression in developing cortex tissues. B) Comparison of fold expression of NDD HNRNPs to non-NDD HNRNPs. C) Heatmap of all HNRNP expression (transcript level expression) in adult brain tissues from GTEx. D) Heatmap of NDD HNRNP expression (transcript level expression) in all tissues from GTEx. Fig. S4. Phenotypic correlations for LGD and missense variant probands. A) Correlation matrix of phenotypes across HNRNP probands with LGD variation (genes with only missense variation excluded) and B) severe missense variation (genes with only LGD variation excluded. * p < 0.05; ** p < 0.01; *** p < 0.001; **** p < 0.0001. Fig. S5. Phenotypic comparisons between LGD and missense variants by HNRNP. Fig. S6. GTEx expression of NDD HNRNPs and genes associated with similarly presenting disorders.",mds,True,findable,0,0,85,1,0,2021-04-20T03:46:20.000Z,2021-04-20T03:46:21.000Z,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)'}]",['12872 Bytes'],,,,"['IsIdenticalTo', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'IsSupplementTo']","[['IsIdenticalTo', '10.6084/m9.figshare.14450784']]"
10.26302/sshade/experiment_cl_20180316_01,MIR reflectance spectra of different samples of carbonaceous chondrites (pellets and fragments),SSHADE/DAYSY (OSUG Data Center),2022,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 spectra of carbonaceous chondrites, obtained by hyperspectral imaging",mds,True,findable,0,0,0,0,0,2022-06-01T21:19:59.000Z,2022-06-01T21:20:00.000Z,inist.sshade,mgeg,"extraterrestrial,carbonaceous chondrite,CM,complex organic-mineral mix,matrix Murray,complex mineral mix,chondrules Murray,CAIs Murray,matrix Murchison,chondrules Murchison,CAIs Murchison,matrix,chondrules,CAIs,CI,bulk Orgueil,Y-793321 matrix,Y-793321 chondrules,Y-793321 CAIs,C ungrouped,B-7904 matrix,B-7904 chondrules,B-7904 CAIs,Jbilet Winselwan matrix,Jbilet Winselwan chondrules,Jbilet Winselwan CAIs,matrix MET01070,chondrules MET01070,CAIs MET01070,matrix QUE97990,chondrules QUE97990,CAIs QUE97990,CR,matrix EET92159,chondrules EET92159,CAIs EET92159,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 Murray'}, {'subject': 'complex mineral mix'}, {'subject': 'chondrules Murray'}, {'subject': 'CAIs Murray'}, {'subject': 'matrix Murchison'}, {'subject': 'chondrules Murchison'}, {'subject': 'CAIs Murchison'}, {'subject': 'matrix'}, {'subject': 'chondrules'}, {'subject': 'CAIs'}, {'subject': 'CI'}, {'subject': 'bulk Orgueil'}, {'subject': 'Y-793321 matrix'}, {'subject': 'Y-793321 chondrules'}, {'subject': 'Y-793321 CAIs'}, {'subject': 'C ungrouped'}, {'subject': 'B-7904 matrix'}, {'subject': 'B-7904 chondrules'}, {'subject': 'B-7904 CAIs'}, {'subject': 'Jbilet Winselwan matrix'}, {'subject': 'Jbilet Winselwan chondrules'}, {'subject': 'Jbilet Winselwan CAIs'}, {'subject': 'matrix MET01070'}, {'subject': 'chondrules MET01070'}, {'subject': 'CAIs MET01070'}, {'subject': 'matrix QUE97990'}, {'subject': 'chondrules QUE97990'}, {'subject': 'CAIs QUE97990'}, {'subject': 'CR'}, {'subject': 'matrix EET92159'}, {'subject': 'chondrules EET92159'}, {'subject': 'CAIs EET92159'}, {'subject': 'laboratory measurement'}, {'subject': 'confocal reflection'}, {'subject': 'micro-imaging'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'normalized reflectance'}]",['10 spectra'],['ASCII'],,,"['IsPartOf', 'IsPartOf', 'IsSourceOf']",
10.6084/m9.figshare.c.6584765,Efficacy and auditory biomarker analysis of fronto-temporal transcranial direct current stimulation (tDCS) in targeting cognitive impairment associated with recent-onset schizophrenia: study protocol for a multicenter randomized double-blind sham-controlled trial,figshare,2023,,Collection,Creative Commons Attribution 4.0 International,"Abstract Background In parallel to the traditional symptomatology, deficits in cognition (memory, attention, reasoning, social functioning) contribute significantly to disability and suffering in individuals with schizophrenia. Cognitive deficits have been closely linked to alterations in early auditory processes (EAP) that occur in auditory cortical areas. Preliminary evidence indicates that cognitive deficits in schizophrenia can be improved with a reliable and safe non-invasive brain stimulation technique called tDCS (transcranial direct current stimulation). However, a significant proportion of patients derive no cognitive benefits after tDCS treatment. Furthermore, the neurobiological mechanisms of cognitive changes after tDCS have been poorly explored in trials and are thus still unclear. Method The study is designed as a randomized, double-blind, 2-arm parallel-group, sham-controlled, multicenter trial. Sixty participants with recent-onset schizophrenia and cognitive impairment will be randomly allocated to receive either active (n=30) or sham (n=30) tDCS (20-min, 2-mA, 10 sessions during 5 consecutive weekdays). The anode will be placed over the left dorsolateral prefrontal cortex and the cathode over the left auditory cortex. Cognition, tolerance, symptoms, general outcome and EAP (measured with EEG and multimodal MRI) will be assessed prior to tDCS (baseline), after the 10 sessions, and at 1- and 3-month follow-up. The primary outcome will be the number of responders, defined as participants demonstrating a cognitive improvement ≥Z=0.5 from baseline on the MATRICS Consensus Cognitive Battery total score at 1-month follow-up. Additionally, we will measure how differences in EAP modulate individual cognitive benefits from active tDCS and whether there are changes in EAP measures in responders after active tDCS. Discussion Besides proposing a new fronto-temporal tDCS protocol by targeting the auditory cortical areas, we aim to conduct a randomized controlled trial (RCT) with follow-up assessments up to 3 months. In addition, this study will allow identifying and assessing the value of a wide range of neurobiological EAP measures for predicting and explaining cognitive deficit improvement after tDCS. The results of this trial will constitute a step toward the use of tDCS as a therapeutic tool for the treatment of cognitive impairment in recent-onset schizophrenia. Trial registration ClinicalTrials.gov NCT05440955. Prospectively registered on July 1st, 2022.",mds,True,findable,0,0,0,0,0,2023-04-13T12:04:23.000Z,2023-04-13T12:04:24.000Z,figshare.ars,otjm,"Medicine,Neuroscience,Physiology,FOS: Biological sciences,Pharmacology,Biotechnology,69999 Biological Sciences not elsewhere classified,Science Policy,111714 Mental Health,FOS: Health sciences","[{'subject': 'Medicine'}, {'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': '69999 Biological Sciences not elsewhere classified', 'schemeUri': 'http://www.abs.gov.au/ausstats/abs@.nsf/0/6BB427AB9696C225CA2574180004463E', 'subjectScheme': 'FOR'}, {'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)'}]",,,,,['IsSupplementTo'],
10.26302/sshade/experiment_lb_20170731_003,"Raw, normalized and baseline-corrected of MIR transmission spectra of GRA95229 matrix grains pressed on diamonds under vacuum at ambiant temperature and 300C",SSHADE/GhoSST (OSUG Data Center),2018,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 GRA95229 at different temperature, under vacuum",mds,True,findable,0,0,0,0,0,2021-05-02T05:48:00.000Z,2021-05-02T05:48:01.000Z,inist.sshade,mgeg,"extraterrestrial,complex organic-mineral mix,matrix GRA95229 heated at 300°C,physically adsorbed phase,adsorbed water,laboratory measurement,transmission,microscopy,MIR,Mid-Infrared,absorbance","[{'subject': 'extraterrestrial'}, {'subject': 'complex organic-mineral mix'}, {'subject': 'matrix GRA95229 heated at 300°C'}, {'subject': 'physically adsorbed phase'}, {'subject': 'adsorbed water'}, {'subject': 'laboratory measurement'}, {'subject': 'transmission'}, {'subject': 'microscopy'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'absorbance'}]",['10 spectra'],['ASCII'],,,"['IsPartOf', 'IsPartOf']",
10.5281/zenodo.8342387,JASPAR 2024 TFBS LOLA databases - Part 3,Zenodo,2023,,Dataset,"Creative Commons Attribution 4.0 International,Open Access","This repository contains the third part of the JASPAR 2024 LOLA databases used by the JASPAR TFBS enrichment tool. For each organism, we provide the LOLA databases for all JASPAR 2024 TFBS sets as compressed directories containing a set of .RDS R objects. Databases are organised by genome assembly. The repository is split into different parts due to file sizes. Below are listed the different parts and the genome assemblies for which they have TFBSs: Part 1: araTha1, ce10, ce11, ci3, danRer11, dm6, sacCer3. Part 2: hg38. Part 3: mm39.",mds,True,findable,0,0,0,0,0,2023-09-14T07:30:29.000Z,2023-09-14T07:30:29.000Z,cern.zenodo,cern,,,,,,,['HasVersion'],"[['IsVersionOf', '10.5281/zenodo.8342387']]"
10.17178/amma-catch.ce.run_ncw,"Surface water dataset (river discharge), within the Wankama watershed (1 km2), Niger","IRD, CNRS-INSU, OSUG, OMP, OREME",2004,en,Dataset,"Creative Commons Attribution 4.0 International,Data access and use are ruled by the AMMA-CATCH data policy.,For any publication using AMMA-CATCH data, authors are asked to:
Mandatory: cite the reference article and the DOI of the observatory
(1) Galle et al. (2018). AMMA-CATCH a Critical Zone Observatory in West Africa Monitoring a Region in Transition. Vadose Zone Journal, 17 (1), 18006.
(2) AMMA-CATCH (1990). AMMA-CATCH : a hydrological, meteorological and ecological observatory on West Africa. IRD, CNRS-INSU, OSUG, OMP, OREME. doi:10.17178/AMMA-CATCH.all
Optional: cite the DOI of each dataset used.
Co-authorship: depending on the contribution of the data to the scientific results obtained, the authors should either propose co-authorship to the data providers or at least acknowledge their contribution.","Documentating of water levels in the koris (temporary creeks), in order to control the runoff in the catchments. Devices are disposed on the same creek to determine possible infiltration areas in their bed.",mds,True,findable,0,0,1,0,0,2018-03-16T15:37:01.000Z,2018-03-16T15:37:01.000Z,inist.osug,jbru,"Discharge,Sahelian climate,Discharge/Flow","[{'subject': 'Discharge', 'subjectScheme': 'main'}, {'subject': 'Sahelian climate', 'subjectScheme': 'main'}, {'subject': 'Discharge/Flow', 'subjectScheme': 'var'}]",,"['CSV', 'NETCDF', 'O&M 1.0']",,,"['Cites', 'IsPartOf', 'IsPartOf']",
10.6084/m9.figshare.c.6771537,"Supplementary material from ""Mirror exposure following visual body-size adaptation does not affect own body image""",The Royal Society,2023,,Collection,Creative Commons Attribution 4.0 International,"Prolonged visual exposure to large bodies produces a thinning aftereffect on subsequently seen bodies, and vice versa. This visual adaptation effect could contribute to the link between media exposure and body shape misperception. Indeed, people exposed to thin bodies in the media, who experience fattening aftereffects, may internalize the distorted image of their body they see in the mirror. This preregistered study tested this internalization hypothesis by exposing 196 young women to an obese adaptor before showing them their reflection in the mirror, or to a control condition. Then, we used a psychophysical task to measure the effects of this procedure on perceptual judgements about their own body size, relative to another body and to the control mirror exposure condition. We found moderate evidence against the hypothesized self-specific effects of mirror exposure on perceptual judgements. Our work strengthens the idea that body size adaptation affects the perception of test stimuli rather than the participants' own body image. We discuss recent studies which may provide an alternative framework to study media-related distortions of perceptual body image.",mds,True,findable,0,0,0,0,0,2023-08-02T11:18:30.000Z,2023-08-02T11:18:31.000Z,figshare.ars,otjm,"Cognitive Science not elsewhere classified,Psychology and Cognitive Sciences not elsewhere classified","[{'subject': 'Cognitive Science not elsewhere classified'}, {'subject': 'Psychology and Cognitive Sciences not elsewhere classified'}]",,,,,,
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,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,0,0,0,0,0,2019-11-16T07:50:58.000Z,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'],,,"['IsPartOf', 'IsPartOf']",
10.26302/sshade/bandlist_raman_natrite,Raman bandlist of Natrite,SSHADE/BANDLIST (OSUG Data Center),2023,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 Natrite at 295K,mds,True,findable,0,0,0,0,0,2023-09-06T19:52:03.000Z,2023-09-06T19:52:03.000Z,inist.sshade,mgeg,"Natrite,Sodium cation,Carbonate anion,Sodium(2+) cation,Na2+,(CO3)2-,Na2CO3,Natrite,non-silicate mineral,carbonate,carbonates, nitrates, borates,anhydrous carbonates,Natrite group,14.01.06.01,05.AA.10,Raman scattering,FIR,MIR,band frequency,band width,band intensity,transition and vibration modes","[{'subject': 'Natrite', 'subjectScheme': 'name'}, {'subject': 'Sodium cation', 'subjectScheme': 'name'}, {'subject': 'Carbonate anion', 'subjectScheme': 'name'}, {'subject': 'Sodium(2+) cation', 'subjectScheme': 'IUPAC name'}, {'subject': 'Na2+', 'subjectScheme': 'formula'}, {'subject': '(CO3)2-', 'subjectScheme': 'formula'}, {'subject': 'Na2CO3', 'subjectScheme': 'formula'}, {'subject': 'Natrite', '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': 'Natrite group', 'subjectScheme': 'Dana group'}, {'subject': '14.01.06.01', 'subjectScheme': 'Dana code'}, {'subject': '05.AA.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'],,,"['IsPartOf', 'IsPartOf', 'IsDerivedFrom', 'Cites', 'IsSourceOf', 'Cites', 'IsSourceOf', 'Cites', 'IsDerivedFrom', 'Cites', 'IsSourceOf', 'Cites', 'IsSourceOf', 'Cites']",
10.5281/zenodo.3256608,easystats/insight: insight 0.19.11,Zenodo,2024,,Software,Creative Commons Attribution 4.0 International,"General
More informative error message for get_varcov() when the requested
vcov-function failed.
Bug fixes
Fixed issue with get_data() for coxme models when sourcewas set to
""modelframe"".",api,True,findable,0,0,0,1,0,2024-05-12T19:44:28.000Z,2024-05-12T19:44:28.000Z,cern.zenodo,cern,,,,,,,"['IsSupplementTo', 'HasVersion', 'HasVersion', 'HasVersion', 'HasVersion', 'HasVersion', 'HasVersion', 'HasVersion', 'HasVersion', 'HasVersion', 'HasVersion', 'HasVersion', 'HasVersion', 'HasVersion', 'HasVersion', 'HasVersion', 'HasVersion', 'HasVersion', 'HasVersion', 'HasVersion', 'HasVersion', 'HasVersion', 'HasVersion', 'HasVersion', 'HasVersion']","[['IsVersionOf', '10.5281/zenodo.3256608']]"
10.5281/zenodo.4628248,Calibration data and analyses,Zenodo,2021,,Dataset,"MIT License,Open Access",This repository contains nearly all the data and notebooks that were used throughout my PhD thesis.,mds,True,findable,0,0,0,0,0,2021-03-23T19:51:46.000Z,2021-03-23T19:51:47.000Z,cern.zenodo,cern,,,,,,,"['IsSupplementTo', 'HasVersion', 'HasVersion']","[['IsVersionOf', '10.5281/zenodo.4628248']]"
10.6084/m9.figshare.12421352,Additional file 1 of Impact of take-home messages written into slide presentations delivered during lectures on the retention of messages and the residents’ knowledge: a randomized controlled study,figshare,2020,,Text,Creative Commons Attribution 4.0 International,Additional file 1. List of lectures.,mds,True,findable,0,0,18,0,0,2020-06-04T03:57:16.000Z,2020-06-04T03:57:17.000Z,figshare.ars,otjm,"Medicine,Sociology,FOS: Sociology,Immunology,FOS: Clinical medicine,Biological Sciences not elsewhere classified,Cancer,Science Policy","[{'subject': 'Medicine'}, {'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': 'Biological Sciences not elsewhere classified'}, {'subject': 'Cancer'}, {'subject': 'Science Policy'}]",['13820 Bytes'],,,,"['References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'IsSupplementTo']",
10.5061/dryad.f7h12,Data from: Poor adherence to guidelines for preventing central line-associated bloodstream infections (CLABSI): results of a worldwide survey,Dryad,2017,en,Dataset,Creative Commons Zero v1.0 Universal,"Background: Central line-associated bloodstream infections (CLABSI) are a
cause of increased morbidity and mortality, and are largely preventable.
We documented attitudes and practices in intensive care units (ICUs) in
2015 in order to assess compliance with CLABSI prevention guidelines.
Methods: Between June and October 2015, an online questionnaire was made
available to medical doctors and nurses working in ICUs worldwide. We
investigated practices related to central line (CL) insertion, maintenance
and measurement of CLABSI-related data following the SHEA guidelines as a
standard. We computed weighted estimates for high, middle and low-income
countries using country population as a weight. Only countries providing
at least 10 complete responses were included in these estimates. Results:
Ninety five countries provided 3407 individual responses; no low income,
14 middle income (MIC) and 27 high income (HIC) countries provided 10 or
more responses. Of the total respondents, 80% (MIC, SE = 1.5) and 81%
(HIC, SE = 1.0) reported availability of written clinical guidelines for
CLABSI prevention in their ICU; 23% (MIC,SE = 1.7) and 62% (HIC,SE = 1.4)
reported compliance to the following (combined) recommendations for CL
insertion: hand hygiene, full barrier precaution, chlorhexidine
>0.5%, no topic or systemic antimicrobial prophylaxis; 60%
(MIC,SE = 2.0) and 73% (HIC,SE = 1.2) reported daily assessment for the
need of a central line. Most considered CLABSI measurement key to quality
improvement, however few were able to report their CLABSI rate.
Heterogeneity between countries was high and country specific results are
made available. Conclusions: This study has identified areas for
improvement in CLABSI prevention practices linked to CL insertion and
maintenance. Priorities for intervention differ between countries.",mds,True,findable,426,97,1,1,0,2016-10-31T16:48:38.000Z,2016-10-31T16:48:39.000Z,dryad.dryad,dryad,"central line-associated bloodstream infection,healthcare associated infection,intensive care","[{'subject': 'central line-associated bloodstream infection'}, {'subject': 'healthcare associated infection'}, {'subject': 'intensive care'}]",['2892577 bytes'],,,,['IsCitedBy'],
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,,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,0,0,0,0,0,2023-06-25T03:11:45.000Z,2023-06-25T03:11:46.000Z,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'],,,,"['IsIdenticalTo', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References']","[['IsIdenticalTo', '10.6084/m9.figshare.23575360']]"
10.57745/ywbdqq,"Transcriptions des brouillons du roman ""La Réticence"" de Jean-Philippe Toussaint",Recherche Data Gouv,2022,,Dataset,,"Les brouillons tapuscrits et annotés de la Réticence (Jean-Philippe Toussaint, Éditions de minuit, 1991) ont été confié par leur auteur à l’UMR LittArts (UMR 5316 – Arts et pratiques du texte, de l’image, de l’écran et de la scène – Université Grenoble Alpes / CNRS), sous la responsabilité scientifique de Brigitte Ferrato-Combe. Réunissant la totalité des documents préparatoires du roman, depuis les premières notes jusqu’aux épreuves et correspondances avec l’éditeur, ce fonds d’archives se révèle particulièrement intéressant pour les études littéraires, stylistiques ou génétiques. Ces brouillons ont été numérisés par le Service Interuniversitaire de Documentation de l’Université Grenoble Alpes où ils ont été momentanément conservés, et font l’objet d’une transcription sur la plateforme collaborative TACT, opération indispensable pour leur donner une pleine lisibilité et permettre les analyses ou recherches automatiques sur le texte. Le schéma de transcription a été élaboré à partir d’XML-TEI avec des choix de balisage assez simples, qui pourront être enrichis ultérieurement. La transcription reproduit à l’identique le texte tapuscrit, en respectant la mise en page (alinéas, retours à la ligne, saut de ligne). Les erreurs éventuelles (orthographe, syntaxe, ponctuation, fautes de frappe) ne sont pas corrigées. Les annotations manuscrites, très nombreuses, sont déchiffrées (dans la limite de la lisibilité) et transcrites, avec un code couleur et une police de caractère permettant de les distinguer du texte tapé. Leur situation dans la page n’est pas reproduite à l’identique ; la diversité des emplacements a été réduite à deux cas de figure : Les ajouts dont l’emplacement dans le texte est clairement défini sur le brouillon sont transcrits au point d’insertion au-dessus du texte tapé (même lorsque leur longueur a contraint l’auteur à les écrire en marge et à les relier par une flèche) Les annotations marginales dont l’emplacement dans le texte n’est pas précisé sont transcrites en bas de la page. Le balisage a été limité à trois fonctions essentielles : Structuration du texte : identification du numéro figurant sur le feuillet, délimitation des paragraphes. Description précise des ratures, déplacements, soulignements, mises en relief, ajouts manuscrits.. Repérage des entités nommées : noms propres de personne ou de lieu (Biaggi, Sasuelo, etc.) noms communs correspondants à des personnages du texte (l’enfant, le chat, l’hôtelier, le pêcheur, etc. ). Les numérisations des fac-simile sont disponibles sur l’entrepôt Nakala, porté par la TGIR TGIR Huma-Num (lien vers l’entrepôt) La ressource contient aussi les feuilles de transformation XSLT qui permettent de transformer la transcription XML en HTML. Elle sont utilisées pour construire le site qui expose les fac-similés et leur transcription (exemple) ainsi que des expérimentations (exemple).",mds,True,findable,314,39,0,0,0,2022-06-22T12:23:30.000Z,2022-07-08T09:02:24.000Z,rdg.prod,rdg,,,,,,,"['HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart']",
10.57745/3vmb3y,Mobi-Switch : a boardgame about urban mobility sustainability,Recherche Data Gouv,2023,,Dataset,,"Mobi-Switch is a board game developed by a team from INRAE's UMR RECOVER, as part of the ANR SwITCh project. The aim of the game is to raise awareness of the sustainability of urban mobility and the challenges associated with it. Players take on the role of elected representatives wishing to improve the sustainability of mobility on their territory. In addition to the collective goal of sustainable mobility, each player is assigned a personal goal. In each round (6 in total, corresponding to the 6 years of a municipal mandate), each player chooses a project from the cards in his or her hand, and tries to convince the others to adhere to his or her project. Each project has an impact on the indicators shown on the game board. It's up to the players to make the right choices to steer mobility towards greater sustainability, while trying to achieve their personal goals.",mds,True,findable,198,10,0,0,0,2023-09-05T08:17:20.000Z,2023-09-05T08:48:43.000Z,rdg.prod,rdg,,,,,,,"['HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart']",
10.6084/m9.figshare.13323658,Additional file 3 of Impact of advance directives on the variability between intensivists in the decisions to forgo life-sustaining treatment,figshare,2020,,Text,Creative Commons Attribution 4.0 International,Additional file 3. Flow chart and timing of the study (Figure).,mds,True,findable,0,0,33,1,0,2020-12-03T04:33:51.000Z,2020-12-03T04:33:56.000Z,figshare.ars,otjm,"Cell Biology,Biotechnology,Biological Sciences not elsewhere classified,Science Policy,Mental Health","[{'subject': 'Cell Biology'}, {'subject': 'Biotechnology'}, {'subject': 'Biological Sciences not elsewhere classified'}, {'subject': 'Science Policy'}, {'subject': 'Mental Health'}]",['131427 Bytes'],,,,"['References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'IsSupplementTo']",
10.17178/ohmcv.adv.cla.13-14.1,"Acoustic Doppler Velocimeter IQ Plus, Claduègne",CNRS - OSUG - OREME,2013,en,Dataset,"Data access and use are ruled by the OHMCV data policy.,The following acknowledging sentence should appear in publications using OHMCV data and products: ""OHMCV is funded by the Institut National des Sciences de l’Univers (INSU/CNRS) and the Observatoire des Sciences de l’Univers de Grenoble (OSUG / Université Grenoble Alpes)”.",This dataset is part of the Cevennes‐Vivarais Mediterranean Hydrometeorological Observatory (OHMCV),mds,True,findable,0,0,1,0,0,2017-03-10T17:09:18.000Z,2017-03-10T17:09:19.000Z,inist.osug,jbru,"Surface Water,ADCP > Acoustic Doppler Current Profiler,Fixed Observation Stations","[{'subject': 'Surface Water', 'subjectScheme': 'main'}, {'subject': 'ADCP > Acoustic Doppler Current Profiler', 'subjectScheme': 'main'}, {'subject': 'Fixed Observation Stations', 'subjectScheme': 'main'}]",,"['CSV', 'ESRI Grid', 'NETCDF']",,,"['Cites', 'IsPartOf']",
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,,Text,Creative Commons Attribution 4.0 International,Authors’ original file for figure 10,mds,True,findable,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'],,,,"['References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References']",
10.26302/sshade/experiment_jd_20171122_001,Ni K edge XAS transmission and XAS fluorescence of Ni complexes (with cysteine-rich ligands) at 10K,SSHADE/FAME (OSUG Data Center),2019,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.",Study of Ni complexes based on tripodal cysteine-rich ligands at different pH,mds,True,findable,0,0,0,0,0,2019-11-15T07:39:05.000Z,2019-11-15T07:39:05.000Z,inist.sshade,mgeg,"solid,commercial,non-oxide ceramic,BN powder,laboratory,anhydrous salt,NiL(N2S2),hydrated salt,Nickel(II) acetylacetonate dihydrate,Nickel(cyclam), 2Cl,molecular solid solution,Frozen solution of $Ni (H_2O)_6 SO_4$,Nickel(cyclam)acetonitrile perchlorate,Frozen solution of $Ni NTA(CysNH_2)_3$ at pH=7.5,Frozen solution of $Ni NTA(CysNH_2)_3$ at pH=9.6,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': 'anhydrous salt'}, {'subject': 'NiL(N2S2)'}, {'subject': 'hydrated salt'}, {'subject': 'Nickel(II) acetylacetonate dihydrate'}, {'subject': 'Nickel(cyclam), 2Cl'}, {'subject': 'molecular solid solution'}, {'subject': 'Frozen solution of $Ni (H_2O)_6 SO_4$'}, {'subject': 'Nickel(cyclam)acetonitrile perchlorate'}, {'subject': 'Frozen solution of $Ni NTA(CysNH_2)_3$ at pH=7.5'}, {'subject': 'Frozen solution of $Ni NTA(CysNH_2)_3$ at pH=9.6'}, {'subject': 'laboratory measurement'}, {'subject': 'transmission'}, {'subject': 'None'}, {'subject': 'hard X'}, {'subject': 'hard X-rays'}, {'subject': 'fluorescence emission'}]",['7 spectra'],['ASCII'],,,"['IsPartOf', 'IsPartOf', 'IsSourceOf']",
10.57745/ruqljl,"Draix-Bleone Observatory spatial data: catchment boundaries, instrument locations and DEM",Recherche Data Gouv,2023,,Dataset,,"This dataset contains spatial information for Draix-Bleone Observatory, including catchment boundaries for the Laval, Moulin, Brusquet, Roubine, Francon, Bouinenc and Galabre catchments, instrument locations, and high-resolution topographic data (DEM) for the Laval, Moulin, Roubine, and Brusquet catchments.",mds,True,findable,39,1,0,0,0,2023-07-03T14:42:16.000Z,2023-07-17T09:46:47.000Z,rdg.prod,rdg,,,,,,,"['HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart']",
10.26302/sshade/bandlist_abs_hcn_hcn-ii,Absorption band list of HCN in natural solid HCN (phase II),SSHADE/BANDLIST (OSUG Data Center),2021,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 HCN in natural solid HCN (phase II) at 35 and 95 K,mds,True,findable,0,0,0,0,0,2023-04-21T07:11:56.000Z,2023-04-21T07:11:56.000Z,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,absorption,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': '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'],,,"['IsPartOf', 'IsPartOf', 'IsDerivedFrom', 'Cites', 'IsSourceOf', 'Cites', 'IsSourceOf', 'Cites', 'IsDerivedFrom', 'Cites', 'IsSourceOf', 'Cites', 'IsSourceOf', 'Cites']",
10.17178/emaa_ortho-h2co_hyperfine_4628f093,Hyperfine excitation of ortho-H2CO by para-H2 collisions,"UGA, CNRS, CNRS-INSU, OSUG",2019,en,Dataset,"Please acknowledge the use of EMAA Database by citing the original articles in which the data were published (BibTeX format available), and adding the following sentence in your publication:
This research has made use of spectroscopic and collisional data from the EMAA database (https://emaa.osug.fr). EMAA is supported by the Observatoire des Sciences de l'Univers de Grenoble (OSUG),Creative Commons Attribution 4.0 International,Data access and use are ruled by the EMAA data policy.",27 hyperfine energy levels / 69 radiative transitions / 324 collisional transitions for para-H2 (10 temperatures in the range 10-100K),mds,True,findable,0,0,0,0,0,2021-11-17T14:01:31.000Z,2021-11-17T14:01:32.000Z,inist.osug,jbru,"target ortho-H2CO,excitationType Hyperfine,collisional excitation,collider.0 para-H2,astrophysics,interstellar medium,comets,circumstellar medium,gas,microwave spectroscopy,infrared spectroscopy,rotational excitation,rovibrational excitation,vibrational excitation,electronic excitation,collisional rate coefficients,fine structure,hyperfine structure","[{'subject': 'target ortho-H2CO', 'subjectScheme': 'main'}, {'subject': 'excitationType Hyperfine', 'subjectScheme': 'main'}, {'subject': 'collisional excitation', 'subjectScheme': 'main'}, {'subject': 'collider.0 para-H2', 'subjectScheme': 'var'}, {'subject': 'astrophysics', 'subjectScheme': 'var'}, {'subject': 'interstellar medium', 'subjectScheme': 'var'}, {'subject': 'comets', 'subjectScheme': 'var'}, {'subject': 'circumstellar medium', 'subjectScheme': 'var'}, {'subject': 'gas', 'subjectScheme': 'var'}, {'subject': 'microwave spectroscopy', 'subjectScheme': 'var'}, {'subject': 'infrared spectroscopy', 'subjectScheme': 'var'}, {'subject': 'rotational excitation', 'subjectScheme': 'var'}, {'subject': 'rovibrational excitation', 'subjectScheme': 'var'}, {'subject': 'vibrational excitation', 'subjectScheme': 'var'}, {'subject': 'electronic excitation', 'subjectScheme': 'var'}, {'subject': 'collisional rate coefficients', 'subjectScheme': 'var'}, {'subject': 'fine structure', 'subjectScheme': 'var'}, {'subject': 'hyperfine structure', 'subjectScheme': 'var'}]",,['Radex'],,,"['Cites', 'IsPartOf', 'References', 'References']",
10.5281/zenodo.3403087,Laboratory modeling of gap-leaping and intruding western boundary currents under different climate change scenarios,Zenodo,2019,,Dataset,"Creative Commons Attribution 4.0 International,Open Access","Western boundary currents (WBCs), such as, the Kuroshio and the Gulf Stream, are very intense currents flowing along the western boundaries of the oceans.<br>WBCs -and their respective extensions- have an important effect on climate because of their huge heat transports, the corresponding air–sea interactions and the role they play in sustaining the global conveyor belt. It is therefore very relevant to analyze WBC dynamics not only through observations and numerical modelling, but also by means of laboratory experiments; to this respect several rotating tank experiments have been performed in recent years.<br>The new laboratory experiments proposed here for the Hydralab+ 19GAPWEBS project are aimed at analyzing the interactions of a WBC with gaps located along the western coast. Examples of such processes include the Gulf Stream leaping from the Yucatan to Florida and the Kuroshio leaping, and partly penetrating, through the South and East China Seas and through the wider gap separating Taiwan to Japan. In the experiments the WBC is produced by a horizontally unsheared current flowing over a topographic beta slope; along the western lateral boundary a sequence of gaps of different widths simulate the openings present in the above mentioned locations.",mds,True,findable,0,0,0,0,0,2019-09-11T07:23:51.000Z,2019-09-11T07:23:51.000Z,cern.zenodo,cern,,,,,,,"['HasVersion', 'IsPartOf']","[['IsVersionOf', '10.5281/zenodo.3403087']]"
10.5281/zenodo.5835982,"FIGURE 5. Bulbophyllum truongtamii Vuong, Aver. V.S.Dang.A. Flowering plant. B in Bulbophyllum section Rhytionanthos (Orchidaceae) in Vietnam with description of new taxa and new national record",Zenodo,2022,,Image,Open Access,"FIGURE 5. Bulbophyllum truongtamii Vuong, Aver. V.S.Dang.A. Flowering plant. B. Leaf apex, adaxial and abaxial side. C. Inflorescences. D. Floral bract. E. Flowers, frontal and back views. F. Median sepal, adaxial and abaxial side. G. Lateral sepals, adaxial and abaxial side. H. Petals, adaxial and abaxial side. I. Lip, views from different sides. J. Pedicel, ovary and column with sepals removed (above), and with all tepals removed (below). K. Column, frontal view. L. Column, half side and side views. M. Anther cap, views from different sides. N. Pollinia. Photos by Truong Ba Vuong, correction and design by L. Averyanov and T. Maisak.",mds,True,findable,0,0,2,2,0,2022-01-11T09:00:56.000Z,2022-01-11T09:00:57.000Z,cern.zenodo,cern,"Biodiversity,Taxonomy,Plantae,Tracheophyta,Liliopsida,Asparagales,Orchidaceae,Bulbophyllum","[{'subject': 'Biodiversity'}, {'subject': 'Taxonomy'}, {'subject': 'Plantae'}, {'subject': 'Tracheophyta'}, {'subject': 'Liliopsida'}, {'subject': 'Asparagales'}, {'subject': 'Orchidaceae'}, {'subject': 'Bulbophyllum'}]",,,,,"['IsPartOf', 'IsPartOf', 'IsPartOf', 'IsPartOf', 'IsCitedBy', 'IsCitedBy', 'HasVersion', 'IsPartOf']","[['IsVersionOf', '10.5281/zenodo.5835982']]"
10.6084/m9.figshare.16851114,Additional file 23 of The mitochondrially-localized nucleoside diphosphate kinase D (NME4) is a novel metastasis suppressor,figshare,2021,,Text,Creative Commons Attribution 4.0 International,Additional file 23: Table S4. Association between NME4 and EMT and tumor invasion marker expression in breast tumors. The relationship between NME4 expression and several key players of EMT and tumor invasion was studied in human breast tumors from the TCGA database.,mds,True,findable,0,0,93,1,0,2021-10-22T04:05:57.000Z,2021-10-22T04:05:59.000Z,figshare.ars,otjm,"Biophysics,Biochemistry,Medicine,Cell Biology,Genetics,FOS: Biological sciences,Molecular Biology,Physiology,Immunology,FOS: Clinical medicine,Developmental Biology,Cancer,Hematology,Infectious Diseases,FOS: Health sciences,Computational Biology","[{'subject': 'Biophysics'}, {'subject': 'Biochemistry'}, {'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': 'Physiology'}, {'subject': 'Immunology'}, {'subject': 'FOS: Clinical medicine', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': 'Developmental Biology'}, {'subject': 'Cancer'}, {'subject': 'Hematology'}, {'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'}]",['15547 Bytes'],,,,"['References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'IsSupplementTo']",
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,,Text,Creative Commons Attribution 4.0 International,Additional file 4.,mds,True,findable,0,0,0,0,0,2023-04-13T18:48:12.000Z,2023-04-13T18:48:12.000Z,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'],,,,"['IsSupplementTo', 'IsIdenticalTo']","[['IsIdenticalTo', '10.6084/m9.figshare.22625617']]"
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,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,0,0,0,0,0,2020-04-20T13:08:46.000Z,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'],,,"['IsPartOf', 'IsPartOf', 'IsSourceOf']",
10.6084/m9.figshare.c.5282401,Performance of the ROX index to predict intubation in immunocompromised patients receiving high-flow nasal cannula for acute respiratory failure,figshare,2021,,Collection,Creative Commons Attribution 4.0 International,"Abstract Background Delayed intubation is associated with high mortality. There is a lack of objective criteria to decide the time of intubation. We assessed a recently described combined oxygenation index (ROX index) to predict intubation in immunocompromised patients. The study is a secondary analysis of randomized trials in immunocompromised patients, including all patients who received high-flow nasal cannula (HFNC). The first objective was to evaluate the accuracy of the ROX index to predict intubation for patients with acute respiratory failure. Results In the study, 302 patients received HFNC. Acute respiratory failure was mostly related to pneumonia (n = 150, 49.7%). Within 2 (1–3) days, 115 (38.1%) patients were intubated. The ICU mortality rate was 27.4% (n = 83). At 6 h, the ROX index was lower for patients who needed intubation compared with those who did not [4.79 (3.69–7.01) vs. 6.10 (4.48–8.68), p < 0.001]. The accuracy of the ROX index to predict intubation was poor [AUC = 0.623 (0.557–0.689)], with low performance using the threshold previously found (4.88). In multivariate analysis, a higher ROX index was still independently associated with a lower intubation rate (OR = 0.89 [0.82–0.96], p = 0.04). Conclusion A ROX index greater than 4.88 appears to have a poor ability to predict intubation in immunocompromised patients with acute respiratory failure, although it remains highly associated with the risk of intubation and may be useful to stratify such risk in future studies.",mds,True,findable,0,0,0,0,0,2021-01-27T04:12:42.000Z,2021-01-27T04:12:46.000Z,figshare.ars,otjm,"Medicine,Sociology,FOS: Sociology,Immunology,FOS: Clinical medicine,Biological Sciences not elsewhere classified,Science Policy,Hematology,Virology","[{'subject': 'Medicine'}, {'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': 'Biological Sciences not elsewhere classified'}, {'subject': 'Science Policy'}, {'subject': 'Hematology'}, {'subject': 'Virology'}]",,,,,,
10.5281/zenodo.594919,spectralpython/spectral: Spectral Python (SPy) 0.23.1,Zenodo,2022,,Software,Open Access,"SPy 0.23.1 Release date: 2022.10.02 Bug Fixes [#143] Eigen{values,vectors} in a <code>GaussianStats</code> weren't sorted in descending order, which is inconsistent with <code>PrincipalComponents</code>. [#144] <code>SpyFile.load</code> was failing on Windows because numpy versions there did not support complex256. [#145] <code>unmix</code> was failing, due to an invalid reference to ""np.inv""",mds,True,findable,0,0,0,0,0,2022-10-02T16:01:03.000Z,2022-10-02T16:01:04.000Z,cern.zenodo,cern,,,,,,,"['IsSupplementTo', 'HasVersion', 'HasVersion', 'HasVersion', 'HasVersion', 'HasVersion', 'HasVersion', 'HasVersion', 'HasVersion', 'HasVersion', 'HasVersion']","[['IsVersionOf', '10.5281/zenodo.594919']]"
10.57745/ktfzqd,Fichiers QGIS et Excel des cas d'étude d'application du protocole d'aide à la décision pour le traitement des embâcles (protocole de Wohl et al. 2019 adapté par Benaksas et Piton 2022),Recherche Data Gouv,2023,,Dataset,,"Chaque archive se rapporte à un cas d'étude du rapport de Benaksas & Piton (2022), à savoir: Le Bresson (Isère) Torrent de montagne et Alloix (Isère) Ruisseau de montagne, Le Lagamas (Hérault) Ruisseau méditerranéen, La Brague (Alpes-Maritimes) Rivière méditerranéenne, La Clamoux (Aude) Rivière torrentielle méditerranéenne. Chaque archive contient trois documents maîtres et les fichiers sources associés permettant de faciliter l'application du protocole de Wohl et al. (2019) tel que adapté par Benaksas & Piton (2022): Le fichier export_csv_vers_shp.qgz est un projet QGIS qui a facilité la transformation en données SIG des fichiers textes (format .csv) importés de l'application Epicollect 5 tel que décrit dans l'Annexe C du rapport de Benaksas et Piton (2023) , L'autre fichier "".gqz"" est un projet QGIS qui facilite l'affichage et l'interprétation des données SIG compilées préalablement aux missions de terrains et sur le terrain via l'application Epicollect 5 tel que décrit dans les Annexe C et D u rapport de Benaksas et Piton (2023) , ResultatsProtocole_epicollecte.xlsx est un tableur Excel qui a facilité la notation des indicateurs de l'approche multicritère, qui permet la modification éventuelle des pondérations entre sous-critères, et qui a mené le calcul des scores pondérés fournis dans le rapport et a préparé les sorties graphiques fournies dans le rapport. Nota: Le cas d'étude du Bréda (Isère) rivière de montagne affluent de l'Isère ayant servi à caler le protocole, les données associées à ce cas d'étude ne sont pas homogènes et ne sont ainsi pas mis librement à disposition. Elles peuvent éventuellement être mises à disposition sur demande directe à Guillaume Piton.",mds,True,findable,112,6,0,0,0,2023-03-06T13:05:38.000Z,2023-03-06T14:03:27.000Z,rdg.prod,rdg,,,,,,,"['HasPart', 'HasPart', 'HasPart', 'HasPart']",
10.6084/m9.figshare.22625626,"Additional file 7 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,,Text,Creative Commons Attribution 4.0 International,Additional file 7.,mds,True,findable,0,0,0,0,0,2023-04-13T18:56:18.000Z,2023-04-13T18:56:18.000Z,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)'}]",['122896 Bytes'],,,,['IsSupplementTo'],
10.57745/tzdeih,PREDIS-MHI Thermal Data,Recherche Data Gouv,2024,,Dataset,,"This dataset contains the thermal energy datasets for the PREDIS-MHI platform of the GreEn-ER building, a tertiary building with more than a thousand sensors used for research, teaching, and administrative activities in Grenoble. The associated datasets presented include readings from the HVAC system for each room in the zone (heating and cooling consumption, temperature and CO2 setpoints, air-flow rates, CO2 levels) and the general Air Handling Unit.",mds,True,findable,132,3,0,0,0,2024-02-16T11:11:21.000Z,2024-03-08T14:23:37.000Z,rdg.prod,rdg,,,,,,,"['HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart']",
10.5281/zenodo.7843135,Modelling and simulating age-dependent pedestrian behaviour with an autonomous vehicle,Zenodo,2023,,Audiovisual,"Creative Commons Attribution 4.0 International,Open Access","Video ""1_SimulationWithoutAgel"" shows the simulation before the modifications of the model and the implementation. Video ""2_SimulationWithAge"" shows the simulation after the modifications of the model and the implementation depending on the age data. Videos of the article: ""Modelling and simulating age-dependent pedestrian behaviour with an autonomous vehicle"" Abstract: In shared spaces, autonomous vehicles (AVs) will have to move efficiently and safely, without normal road signage, and with other users such as pedestrians, cyclists and drivers. To achieve this, AVs need to anticipate the behaviours of other road users in order to adapt their navigation accordingly. This paper focuses on age-related pedestrian behaviours with an autonomous vehicle. Looking at age as one of the main factors determining behaviour, a literature review is conducted. The results are used to integrate age-dependent pedestrian behaviours into a model for simulating more realistic pedestrian behaviours in shared spaces with an AV.",mds,True,findable,0,0,0,0,0,2023-04-22T13:30:38.000Z,2023-04-22T13:30:38.000Z,cern.zenodo,cern,,,,,,,"['HasVersion', 'HasVersion', 'HasVersion', 'HasVersion']","[['IsVersionOf', '10.5281/zenodo.7843135']]"
10.5281/zenodo.3407126,Experiments on Grain Size Segregation in Bedload Transport on a steep Slope,Zenodo,2019,,Dataset,"Creative Commons Attribution 4.0 International,Open Access","This dataset is the basis of the publication: Frey, P., Lafaye de Micheaux, H., Bel, C., Maurin, R., Rorsman, K., Martin, T., Ducottet, C., 2020. Experiments on grain size segregation in bedload transport on a steep slope. Advances in Water Resources. https://doi.org/10.1016/j.advwatres.2019.103478. Experiments consisted in bedload of two-size spherical glass beads transported at equilibrium by a turbulent supercritical free surface water flow over a mobile bed. Two runs, one with a low rate of large black beads (S6), the other with a higher rate (S20), are considered. This dataset consists in: - temporal sequences of uncompressed tif images corresponding to figure 5 showing small particle concentration : 9 sequences for run S6 (BillesBaumerMicro) and 9 sequences for run S20 (BillesbaumerAmontSequence) - two ‘.mat’ file corresponding to runs S6 (trackData_Micro_S6.mat) and S20 (trackData_Amont_S20.mat) giving all the trajectories of all beads. Trajectories were obtained with a tracking algorithm developed by H. Lafaye de Micheaux et al. (2016,2018) building on Hergault et al. (2010). The code implementing the tracking algorithm is available on https://github.com/hugolafaye/BeadTracking. The files contain the variable 'trackData' being a cell array of tracking matrices. There is one tracking matrix for each image of the sequence giving in particular the coordinate and velocity of each bead. Complete information on data format is given in the file readme.txt in the github BeadTracking package. Parameter files necessary to replicate our results from the images are also available on the BeadTracking package as well as on https://doi.org/10.5281/zenodo.3454628 where a 1000-image ground truth is stored. Important note: Experimental images were grabbed with the flow from right to the left implying for instance negative values for the x-coordinate of velocities. To comply with a traditional convention, images and associated results in the publication are shown from left to the right.",mds,True,findable,5,0,0,0,0,2019-10-14T14:33:25.000Z,2019-10-14T14:33:25.000Z,cern.zenodo,cern,"Sediment transport, bedload, experimental, segregation, two-phase flow, granular flow, particle tracking","[{'subject': 'Sediment transport, bedload, experimental, segregation, two-phase flow, granular flow, particle tracking'}]",,,,,['HasVersion'],"[['IsVersionOf', '10.5281/zenodo.3407126']]"
10.15778/resif.yi2008,Seismic network YI:SIMBAAD temporary experiment - Anatolia Eastern transect (RESIF-SISMOB),RESIF - Réseau Sismologique et géodésique Français,2008,en,Other,"Open Access,Creative Commons Attribution 4.0 International",Temporary seismic profile across West-Central Anatolia. Goal: imaging of the lithospheric structure using earthquake data. 23 seismic stations with ~15 km spacing along a North-South line at 30.5°E. Sensors: mostly Güralp CMG40-T. Digitizers: Agecodagis Minititan,mds,True,findable,0,0,0,1,0,2014-12-09T14:49:34.000Z,2014-12-09T14:49:34.000Z,inist.resif,vcob,"Central Anatolia,Crustal structure,Lithospheric structure,Seismic imaging","[{'subject': 'Central Anatolia'}, {'subject': 'Crustal structure'}, {'subject': 'Lithospheric structure'}, {'subject': 'Seismic imaging'}]",,,,,['IsCitedBy'],
10.57745/ellxjf,Answers to a survey about perceptions of mobility,Recherche Data Gouv,2024,,Dataset,,"This dataset contains answers to a survey about mobility perceptions, that was run online (Framaform) during March-July 2023.",mds,True,findable,42,2,0,0,0,2024-03-27T18:47:25.000Z,2024-04-09T13:39:58.000Z,rdg.prod,rdg,,,,,,,"['HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart']",
10.17178/emaa_(13c)o_rotation_30dfe01d,"Rotation excitation of [13C]O by ortho-H2O, para-H2 and para-H2O collisions","UGA, CNRS, CNRS-INSU, OSUG",2021,en,Dataset,"Please acknowledge the use of EMAA Database by citing the original articles in which the data were published (BibTeX format available), and adding the following sentence in your publication:
This research has made use of spectroscopic and collisional data from the EMAA database (https://emaa.osug.fr). EMAA is supported by the Observatoire des Sciences de l'Univers de Grenoble (OSUG),Creative Commons Attribution 4.0 International,Data access and use are ruled by the EMAA data policy.",14 rotation energy levels / 13 radiative transitions / 55 collisional transitions for para-H2O (20 temperatures in the range 5-100K) / 55 collisional transitions for ortho-H2O (20 temperatures in the range 5-100K) / 10 collisional transitions for para-H2 (9 temperatures in the range 2-40K),mds,True,findable,0,0,4,0,0,2022-02-07T11:23:59.000Z,2022-02-07T11:24:00.000Z,inist.osug,jbru,"target [13C]O,excitationType Rotation,collisional excitation,collider.0 para-H2O,collider.1 ortho-H2O,collider.2 para-H2,astrophysics,interstellar medium,comets,circumstellar medium,gas,microwave spectroscopy,infrared spectroscopy,rotational excitation,rovibrational excitation,vibrational excitation,electronic excitation,collisional rate coefficients,fine structure,hyperfine structure","[{'subject': 'target [13C]O', 'subjectScheme': 'main'}, {'subject': 'excitationType Rotation', 'subjectScheme': 'main'}, {'subject': 'collisional excitation', 'subjectScheme': 'main'}, {'subject': 'collider.0 para-H2O', 'subjectScheme': 'var'}, {'subject': 'collider.1 ortho-H2O', 'subjectScheme': 'var'}, {'subject': 'collider.2 para-H2', 'subjectScheme': 'var'}, {'subject': 'astrophysics', 'subjectScheme': 'var'}, {'subject': 'interstellar medium', 'subjectScheme': 'var'}, {'subject': 'comets', 'subjectScheme': 'var'}, {'subject': 'circumstellar medium', 'subjectScheme': 'var'}, {'subject': 'gas', 'subjectScheme': 'var'}, {'subject': 'microwave spectroscopy', 'subjectScheme': 'var'}, {'subject': 'infrared spectroscopy', 'subjectScheme': 'var'}, {'subject': 'rotational excitation', 'subjectScheme': 'var'}, {'subject': 'rovibrational excitation', 'subjectScheme': 'var'}, {'subject': 'vibrational excitation', 'subjectScheme': 'var'}, {'subject': 'electronic excitation', 'subjectScheme': 'var'}, {'subject': 'collisional rate coefficients', 'subjectScheme': 'var'}, {'subject': 'fine structure', 'subjectScheme': 'var'}, {'subject': 'hyperfine structure', 'subjectScheme': 'var'}]",,['Radex'],,,"['Cites', 'IsPartOf', 'References', 'References', 'References']",
10.7914/k2rg-gn94,Peri-glacial an glacial risk study seismic network,International Federation of Digital Seismograph Networks,2024,,Dataset,,"Seismic network and temporary surveys deployed in the Mont Blanc and Vanoise mountain ranges, french Alps, devoted to the study of glacial and peri-glacial risk, landslides, rockfalls and slope stability. Continuous data allow in depth analysis of ambient seismic noise, but also micro-sismicity and regional seismicity.
These network and survey are conducted in the framework of the ""PAPROG"" National action plan for the prevention of glacial and periglacial risks, financed by the French Ministry of the Environment's General Directorate for Risk Prevention.",api,True,findable,0,0,0,0,0,2024-04-17T16:57:03.000Z,2024-04-17T16:57:04.000Z,iris.iris,iris,,,['2000000 MB'],['SEED data'],,,,
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,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,0,0,0,0,0,2021-05-10T12:27:40.000Z,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'],,,"['IsPartOf', 'IsPartOf', 'IsSourceOf']",
10.5281/zenodo.11164067,A Memristive Neural Decoder for Cryogenic Fault-Tolerant Quantum Error Correction - Simulation Data,Zenodo,2024,en,Dataset,Creative Commons Attribution 4.0 International,"Simulation output data used to generate figures of the paper: ""A Memristive Neural Decoder for Cryogenic Fault-Tolerant Quantum Error Correction""",api,True,findable,0,0,0,1,1,2024-05-09T14:50:50.000Z,2024-05-09T14:50:51.000Z,cern.zenodo,cern,"Machine learning,Quantum computers,Nanoelectronics","[{'subject': 'Machine learning', 'subjectScheme': 'EuroSciVoc'}, {'subject': 'Quantum computers', 'subjectScheme': 'EuroSciVoc'}, {'subject': 'Nanoelectronics', 'subjectScheme': 'EuroSciVoc'}]",,,,,"['IsSupplementTo', 'HasVersion']",
10.17178/emaa_oh_fine_73f2c321,"Fine excitation of OH by H, ortho-H2 and para-H2 collisions","UGA, CNRS, CNRS-INSU, OSUG",2022,en,Dataset,"Please acknowledge the use of EMAA Database by citing the original articles in which the data were published (BibTeX format available), and adding the following sentence in your publication:
This research has made use of spectroscopic and collisional data from the EMAA database (https://emaa.osug.fr). EMAA is supported by the Observatoire des Sciences de l'Univers de Grenoble (OSUG),Creative Commons Attribution 4.0 International,Data access and use are ruled by the EMAA data policy.",20 fine energy levels / 50 radiative transitions / 190 collisional transitions for para-H2 (7 temperatures in the range 10-150K) / 190 collisional transitions for ortho-H2 (7 temperatures in the range 10-150K) / 66 collisional transitions for H (11 temperatures in the range 5-500K),mds,True,findable,0,0,0,0,0,2023-12-07T15:51:30.000Z,2023-12-07T15:51:30.000Z,inist.osug,jbru,"target OH,excitationType Fine,collisional excitation,collider.0 para-H2,collider.1 ortho-H2,collider.2 H,astrophysics,interstellar medium,comets,circumstellar medium,gas,microwave spectroscopy,infrared spectroscopy,rotational excitation,rovibrational excitation,vibrational excitation,electronic excitation,collisional rate coefficients,fine structure,hyperfine structure","[{'subject': 'target OH', 'subjectScheme': 'main'}, {'subject': 'excitationType Fine', 'subjectScheme': 'main'}, {'subject': 'collisional excitation', 'subjectScheme': 'main'}, {'subject': 'collider.0 para-H2', 'subjectScheme': 'var'}, {'subject': 'collider.1 ortho-H2', 'subjectScheme': 'var'}, {'subject': 'collider.2 H', 'subjectScheme': 'var'}, {'subject': 'astrophysics', 'subjectScheme': 'var'}, {'subject': 'interstellar medium', 'subjectScheme': 'var'}, {'subject': 'comets', 'subjectScheme': 'var'}, {'subject': 'circumstellar medium', 'subjectScheme': 'var'}, {'subject': 'gas', 'subjectScheme': 'var'}, {'subject': 'microwave spectroscopy', 'subjectScheme': 'var'}, {'subject': 'infrared spectroscopy', 'subjectScheme': 'var'}, {'subject': 'rotational excitation', 'subjectScheme': 'var'}, {'subject': 'rovibrational excitation', 'subjectScheme': 'var'}, {'subject': 'vibrational excitation', 'subjectScheme': 'var'}, {'subject': 'electronic excitation', 'subjectScheme': 'var'}, {'subject': 'collisional rate coefficients', 'subjectScheme': 'var'}, {'subject': 'fine structure', 'subjectScheme': 'var'}, {'subject': 'hyperfine structure', 'subjectScheme': 'var'}]",,['Radex'],,,"['Cites', 'IsPartOf', 'References', 'References', 'References']",
10.57745/lutmne,Long-term global mining data to 2019,Recherche Data Gouv,2022,,Dataset,,"This dataset brings together several types of mining data for 50 mining elements* provided by the U.S. Geological Survey (USGS). Long trend global mining production to 2019 and global reserves data to 2021 and global resources when available are extracted from annual reports, documentation and raw data. *Aluminium, Antimony, Arsenic, Bauxite, Beryllium, Boron, Bromine, Cadmium, Cesium, Chromium, Cobalt, Copper, Gallium, Germanium, Gold, Graphite, Hafnium, Indium, Iodine, Iron, Lead, Lithium, Magnesium, Manganese, Mercury, Molybdenum, Nickel, Niobium, Phosphorus, Platinum group metal, Rare Earths, Rhenium, Rubidium, Selenium, Silica, Silicon, Silver, Strontium, Sulfur, Tantalum, Tellurium, Thallium, Thorium, Tin, Titanium, Tungsten, Vanadium, Yttrium, Zinc, Zirconium",mds,True,findable,131,15,0,0,0,2022-12-07T11:17:07.000Z,2022-12-09T19:55:08.000Z,rdg.prod,rdg,,,,,,,['HasPart'],
10.5281/zenodo.10204742,"Supplementary material to ""SnowPappus v1.0, a blowing-snow model for large-scale applications of Crocus snow scheme"" : Pleiades snow depth maps analysis",Zenodo,2023,,Dataset,Creative Commons Attribution 4.0 International,"This Folder contains :
- necessary codes to reprduce Fig. 5, 12 and 13 of the third version of the submitted manuscript SnowPappus v1.0, a blowing-snow model for large-scale applications of Crocus snow scheme""
- necessary data to run these codes, including extracts of simulation outputs
- A readme.txt which explains how to run everything
",api,True,findable,0,0,0,0,0,2023-11-24T18:50:44.000Z,2023-11-24T18:50:45.000Z,cern.zenodo,cern,,,,,,,['HasVersion'],"[['IsVersionOf', '10.5281/zenodo.10204742']]"
10.5281/zenodo.3462168,Environmental co-benefits and adverse side-effects of alternative power sector decarbonization strategies,Zenodo,2019,en,Software,"Creative Commons Attribution Share Alike 4.0 International,Open Access","This package contains the data and source code used in preparation for the<br> paper ""Environmental co-benefits and adverse side-effects of alternative power<br> sector decarbonization strategies"" by Gunnar Luderer et al., published in Nature<br> Communications.",mds,True,findable,10,0,0,0,0,2019-11-05T21:11:41.000Z,2019-11-05T21:11:41.000Z,cern.zenodo,cern,,,,,,,"['IsSupplementTo', 'HasVersion', 'HasVersion']","[['IsVersionOf', '10.5281/zenodo.3462168']]"
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,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,0,0,0,0,0,2020-10-29T16:52:13.000Z,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'],,,"['IsPartOf', 'IsPartOf']",
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,,Text,Creative Commons Attribution 4.0 International,Supplementary Material 1,mds,True,findable,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'],,,,"['IsSupplementTo', 'IsIdenticalTo']","[['IsIdenticalTo', '10.6084/m9.figshare.22735399']]"
10.6084/m9.figshare.23822154,Dataset for the main experiment from Mirror exposure following visual body-size adaptation does not affect own body image,The Royal Society,2023,,Dataset,Creative Commons Attribution 4.0 International,Data for the main experiment in CSV format.,mds,True,findable,0,0,0,0,0,2023-08-02T11:18:26.000Z,2023-08-02T11:18:26.000Z,figshare.ars,otjm,"Cognitive Science not elsewhere classified,Psychology and Cognitive Sciences not elsewhere classified","[{'subject': 'Cognitive Science not elsewhere classified'}, {'subject': 'Psychology and Cognitive Sciences not elsewhere classified'}]",['29026 Bytes'],,,,"['IsIdenticalTo', 'IsSupplementTo']","[['IsIdenticalTo', '10.6084/m9.figshare.23822154']]"
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,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,0,0,0,0,0,2019-11-15T20:28:06.000Z,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'],,,"['IsPartOf', 'IsPartOf']",
10.60527/qsw1-vr24,TIC et mobilisation : le cas du Congo,"Univ. Grenoble Alpes, GRESEC",2015,fr,Audiovisual,Droit commun de la propriété intellectuelle,"Intervention de Théodora MIERE : Maître de Conférences en Sciences de l’Information et de la Communication. Université de Versailles Saint-Quentin en Yvelines. Chercheur au Larequoi - IUT de Mantes en Yvelines. Le 4 mai 2015 à l'Institut de la Communication et des Médias (Université Stendhal Grenoble 3). Communication au colloque international ""La communication numérique au cœur des sociétés : dispositifs, logiques de développement et pratiques"". ",api,True,findable,0,0,0,0,0,2024-03-06T22:51:53.000Z,2024-03-06T22:51:54.000Z,fmsh.prod,fmsh,"Sciences de l'information et de la communication,Communication","[{'subject': ""Sciences de l'information et de la communication""}, {'subject': 'Communication'}]",,['video/mp4'],,,['IsPartOf'],
10.26302/sshade/experiment_op_20230220_001,Cu K edge XAS HERFD of Cu metallic powder (2% weight in BN),SSHADE/FAME (OSUG Data Center),2023,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,0,0,0,0,0,2023-02-20T14:15:37.000Z,2023-02-20T14:15:37.000Z,inist.sshade,mgeg,"solid,commercial,non-oxide ceramic,BN powder,metal,Cu,laboratory measurement,fluorescence emission,None,hard X,hard X-rays","[{'subject': 'solid'}, {'subject': 'commercial'}, {'subject': 'non-oxide ceramic'}, {'subject': 'BN powder'}, {'subject': 'metal'}, {'subject': 'Cu'}, {'subject': 'laboratory measurement'}, {'subject': 'fluorescence emission'}, {'subject': 'None'}, {'subject': 'hard X'}, {'subject': 'hard X-rays'}]",['2 spectra'],['ASCII'],,,"['IsPartOf', 'IsPartOf']",
10.5281/zenodo.3568738,Magnetism and anomalous transport in the Weyl semimetal PrAlGe: Possible route to axial gauge fields,Zenodo,2019,,Dataset,"Creative Commons Attribution 4.0 International,Open Access","The file ManuscriptDataFiles.7z contains the raw experimental data from which the figures are made in the manuscript entitled ""Magnetism and anomalous transport in the Weyl semimetal PrAlGe: Possible route to axial gauge fields"" that appeared in npj Quantum Materials <strong>5</strong>, 5 (2020). Paper Abstract: In magnetic Weyl semimetals, where magnetism breaks time-reversal symmetry, large magnetically sensitive anomalous transport responses are anticipated that could be useful for topological spintronics. The identification of new magnetic Weyl semimetals is therefore in high demand, particularly since in these systems Weyl node configurations may be easily modified using magnetic fields. Here we explore experimentally the magnetic semimetal PrAlGe, and unveil a direct correspondence between easy-axis Pr ferromagnetism and anomalous Hall and Nernst effects. With sizes of both the anomalous Hall conductivity and Nernst effect in good quantitative agreement with first principles calculations, we identify PrAlGe as a system where magnetic fields can connect directly to Weyl nodes via the Pr magnetization. Furthermore, we find the predominantly easy-axis ferromagnetic ground state co-exists with a low density of nanoscale textured magnetic domain walls. We describe how such nanoscale magnetic textures could serve as a local platform for tunable axial gauge fields of Weyl fermions.",mds,True,findable,0,0,0,0,0,2020-01-17T14:00:06.000Z,2020-01-17T14:00:07.000Z,cern.zenodo,cern,"magnetism, semimetal, Hall effect, magnetization, Nernst effect, neutron scattering Weyl","[{'subject': 'magnetism, semimetal, Hall effect, magnetization, Nernst effect, neutron scattering Weyl'}]",,,,,['HasVersion'],"[['IsVersionOf', '10.5281/zenodo.3568738']]"
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,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,0,0,0,0,0,2019-12-30T09:46:18.000Z,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'],,,"['IsPartOf', 'IsPartOf', 'IsSourceOf']",
10.60527/3ygq-v524,"Des plates-formes numériques dans les champs de l’éducation, formation, orientation, révélatrices des mutations industrielles et sociales","Univ. Grenoble Alpes, GRESEC",2015,fr,Audiovisual,Droit commun de la propriété intellectuelle,"Intervention de Laurent Petit : Maître de conférences HDR. LabSIC, Université Paris 13. Communication préparée avec Yolande COMBES : Maître de conférences, Professeur. LabSIC, Université Paris 13. Le 4 mai 2015 à l'Institut de la Communication et des Médias (Université Stendhal Grenoble 3). Communication au colloque international ""La communication numérique au cœur des sociétés : dispositifs, logiques de développement et pratiques"". ",api,True,findable,0,0,0,0,0,2024-03-06T22:50:48.000Z,2024-03-06T22:50:48.000Z,fmsh.prod,fmsh,"Sciences de l'information et de la communication,Communication","[{'subject': ""Sciences de l'information et de la communication""}, {'subject': 'Communication'}]",,['video/mp4'],,,['IsPartOf'],
10.26302/sshade/experiment_bms_20150101_002,VUV absorbance spectra between 10 and 130 K of amorphous CH3CH2CN deposited at 10 K,SSHADE/ACID (OSUG Data Center),2019,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 CH3CH2CN deposited at 10 K,mds,True,findable,0,0,0,0,0,2021-03-01T20:12:49.000Z,2021-03-01T20:12:50.000Z,inist.sshade,mgeg,"laboratory,organic molecular solid,amorphous CH3CH2CN ice,laboratory measurement,transmission,macroscopic,VUV,Vacuum Ultraviolet,absorbance","[{'subject': 'laboratory'}, {'subject': 'organic molecular solid'}, {'subject': 'amorphous CH3CH2CN ice'}, {'subject': 'laboratory measurement'}, {'subject': 'transmission'}, {'subject': 'macroscopic'}, {'subject': 'VUV'}, {'subject': 'Vacuum Ultraviolet'}, {'subject': 'absorbance'}]",['4 spectra'],['ASCII'],,,"['IsPartOf', 'IsSourceOf']",
10.26302/sshade/experiment_gs_20170712_003,Ag K edge XAS transmission of natural Ag2S,SSHADE/FAME (OSUG Data Center),2018,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,0,0,0,0,0,2019-12-05T14:04:50.000Z,2019-12-05T14:05:09.000Z,inist.sshade,mgeg,"solid,commercial,non-oxide ceramic,BN powder,natural terrestrial,sulfide,Natural acanthite,laboratory measurement,transmission,None,hard X,hard X-rays","[{'subject': 'solid'}, {'subject': 'commercial'}, {'subject': 'non-oxide ceramic'}, {'subject': 'BN powder'}, {'subject': 'natural terrestrial'}, {'subject': 'sulfide'}, {'subject': 'Natural acanthite'}, {'subject': 'laboratory measurement'}, {'subject': 'transmission'}, {'subject': 'None'}, {'subject': 'hard X'}, {'subject': 'hard X-rays'}]",['1 spectrum'],['ASCII'],,,"['IsPartOf', 'IsPartOf', 'IsSourceOf']",
10.26302/sshade/experiment_gs_20170713_003,Ag K edge XAS transmission of Ag2CO3,SSHADE/FAME (OSUG Data Center),2018,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,0,0,0,0,0,2019-12-05T13:51:19.000Z,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'],,,"['IsPartOf', 'IsPartOf', 'IsSourceOf']",
10.26302/sshade/experiment_ik_20180418_001,Ce L3 edge XAS HERFD of CeO2 (nanos) at 10K,SSHADE/FAME (OSUG Data Center),2018,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,0,0,0,0,0,2019-12-05T14:10:39.000Z,2019-12-05T14:10:39.000Z,inist.sshade,mgeg,"solid,commercial,non-oxide ceramic,BN powder,oxide,CeO2,laboratory measurement,fluorescence emission,None,hard X,hard X-rays","[{'subject': 'solid'}, {'subject': 'commercial'}, {'subject': 'non-oxide ceramic'}, {'subject': 'BN powder'}, {'subject': 'oxide'}, {'subject': 'CeO2'}, {'subject': 'laboratory measurement'}, {'subject': 'fluorescence emission'}, {'subject': 'None'}, {'subject': 'hard X'}, {'subject': 'hard X-rays'}]",['1 spectrum'],['ASCII'],,,"['IsPartOf', 'IsPartOf', 'IsSourceOf']",
10.6084/m9.figshare.20080019.v4,Views Evolution 5 Minutes Frequency,figshare,2022,,Dataset,Creative Commons Attribution 4.0 International,"This dataset contains 1012 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,0,0,0,0,0,2022-11-24T11:47:40.000Z,2022-11-24T11:47:41.000Z,figshare.ars,otjm,"Applications in physical sciences,Complex physical systems","[{'subject': 'Applications in physical sciences'}, {'subject': 'Complex physical systems'}]",['552808145 Bytes'],,,,['IsPreviousVersionOf'],
10.17178/gnss.products.southamerica_gipsyx.daily,Metadata and GNSS daily position solutions for permanent GNSS stations in South America,"CNRS, OSUG, ISTERRE",2023,en,Dataset,"License: CC BY-NC-ND 4.0,Data access and use are ruled by the OSUG data policy.,The following acknowledging sentence should appear in publications using ISTerre GNSS products: ""GNSS products are calculated and provided by the Institut of Sciences de la Terre (ISTerre), belonging to the Institut National des Sciences de l’Univers (INSU/CNRS) and the Observatoire des Sciences de l’Univers de Grenoble (OSUG / Université Grenoble Alpes)"".
You are invited to contact the PI(s) or lead scientist for more information about the data and to include the acknowledgement sentence in any publication using the data.","This dataset includes metadata, as well as daily position solutions for a large number (>700) of permanent GNSS stations in South America. These data were processed by ISTerre in the frame of the DEEP-trigger project. The products are daily position time series (North, East and Vertical), in the ITRF14 reference frame, calculated from RINEX files using the PPP strategy with GIPSYX software.",mds,True,findable,0,0,1,1,0,2023-04-08T13:17:57.000Z,2023-04-08T13:18:03.000Z,inist.osug,jbru,"GNSS products,GNSS data analysis,Time serie positioning","[{'subject': 'GNSS products', 'subjectScheme': 'main'}, {'subject': 'GNSS data analysis', 'subjectScheme': 'var'}, {'subject': 'Time serie positioning', 'subjectScheme': 'var'}]",,"['pos', 'PBO']",,,"['Cites', 'IsPartOf']",
10.5281/zenodo.5243208,Latin DBnary archive in original Lemon format,Zenodo,2021,la,Dataset,"Creative Commons Attribution Share Alike 4.0 International,Open Access","The DBnary dataset is an extract of Wiktionary data from many language editions in RDF Format. Until July 1st 2017, the lexical data extracted from Wiktionary was modeled using the lemon vocabulary. This dataset contains the full archive of all DBnary dumps in Lemon format containing lexical information from Latin language edition, ranging from 6th June 2015 to 1st July 2017. After July 2017, DBnary data has been modeled using the ontolex model and will be available in another Zenodo entry.",mds,True,findable,0,0,0,0,0,2021-08-24T10:32:45.000Z,2021-08-24T10:32:46.000Z,cern.zenodo,cern,"Wiktionary,Lemon,Lexical Data,RDF","[{'subject': 'Wiktionary'}, {'subject': 'Lemon'}, {'subject': 'Lexical Data'}, {'subject': 'RDF'}]",,,,,"['IsDocumentedBy', 'HasVersion', 'IsPartOf']","[['IsVersionOf', '10.5281/zenodo.5243208']]"
10.5281/zenodo.5527126,Imprints of Ocean Chaotic Intrinsic Variability on Bottom Pressure and Implications for Data and Model Analyses,Zenodo,2021,,Dataset,"Creative Commons Attribution 3.0 United States,Open Access","These data are used for the manuscript ""Imprints of Ocean Chaotic Intrinsic Variability on Bottom Pressure and Implications for Data and Model Analyses"" to be submitted to Geophysical Research Letter. Uploaded data include: [1] ext_int_quater_deg.nc: atmospherically driven and intrinsic variations for subseasonal, intra-annual and mean seasonal bottom pressure signals at model original resolution. [2] ext_int_3deg.nc: atmospherically driven and intrinsic variations for smoothed subseasonal and intra-annual bottom pressure signals at 3*3 degree resolution. [3] ext_int_10deg.nc: atmospherically driven and intrinsic variations for smoothed intra-annual bottom pressure signals at 10*10 degree resolution. [4] meanseason_timeseries.nc: Time series of mean seasonal bottom pressure signals from all 50 ensemble members over Agulhas Current region and Argentine Basin.",mds,True,findable,0,0,0,0,0,2021-09-24T19:20:00.000Z,2021-09-24T19:20:01.000Z,cern.zenodo,cern,,,,,,,['HasVersion'],"[['IsVersionOf', '10.5281/zenodo.5527126']]"
10.5281/zenodo.3237322,The exercise paradox: Avoiding physical inactivity stimuli requires higher response inhibition,Zenodo,2020,en,Dataset,"Creative Commons Attribution 4.0 International,Open Access","<strong>Dataset related to the paper on Response inhibition to physical inactivity stimuli using go/no-go tasks. </strong> This dataset includes: <strong>1) A codebook (including the name of the main variables)</strong> --> ""code_book_Go_noGo_Miller.xlsx"" <strong>2) Raw data of the behavioral outcomes (i.e., reaction times) of the affective go/no-go task</strong> --> ""corrected.behavioral.data.csv"" --> ""correct_Order.csv"" <strong>3) Self-reported data </strong> --> ""Self_report_data.csv"" <strong>3) EEG data </strong> --> ""gng_data"" <strong>5) R script for the data management (i.e., from the raw data to data ready to be analyzed)</strong> --> ""Data_management_Self_report_go_no_go_Miller.R"" for the self-reported data (return the file: ""Data_SR_final.RData"") --> ""Data_management_behav_go_no_go_Miller.R"" for the behavioral outcomes (return the file: ""Data_GNG_behav.RData"") --> Data ready to be analyzed ""Data_GNG_final_all.RData"" <strong>6) Eprime script for the affective go/no-go task (""Go_no_go_task.zip"")</strong> --> Images depicting physical activity and physical inactivity stimuli were kindly Share by Kullmann et al. (2014) <strong>7) R script for the models tested</strong> <strong>--> ""</strong>Models_GoNogo_Miller_VZenodo.R"" for behavioral data --> ""Models_EEG_GoNogo.R"" for EEG data",mds,True,findable,0,0,0,0,0,2021-01-06T13:17:06.000Z,2021-01-06T13:17:41.000Z,cern.zenodo,cern,"Response inhibition,inhibitory control,go/no-go,energetic cost minimization,physical activity","[{'subject': 'Response inhibition'}, {'subject': 'inhibitory control'}, {'subject': 'go/no-go'}, {'subject': 'energetic cost minimization'}, {'subject': 'physical activity'}]",,,,,"['HasVersion', 'HasVersion']","[['IsVersionOf', '10.5281/zenodo.3237322']]"
10.5281/zenodo.11058212,An experimental dataset to explore the size ratio impact on an intruder segregating in bedload transport,Zenodo,2024,,Dataset,Creative Commons Attribution 4.0 International,"This repository gathers :
The treated data used in the article ""Exploring the size ratio impact on an intruder segregating in bedload transport"" from Dedieu B., Rousseau H., Frey P. and Chauchat J. (currently under review in Physical Review of Fluids),
Some re-computed data from the experiments of Rousseau H. et al.(2022) in csv format,
A python3 package codes used to load the data.
Explanations on how to use the codes and how the data are organized can be found in the README.md.
Feel free to contact the authors if you need more information or wish to access the raw image data.",api,True,findable,0,0,0,0,0,2024-04-24T15:45:42.000Z,2024-04-24T15:45:42.000Z,cern.zenodo,cern,"Bedload,Grain-size segregation,Granular physics,Sediment transport","[{'subject': 'Bedload'}, {'subject': 'Grain-size segregation'}, {'subject': 'Granular physics'}, {'subject': 'Sediment transport'}]",,,,,"['References', 'HasVersion']","[['IsVersionOf', '10.5281/zenodo.11058212']]"
10.6084/m9.figshare.c.6804540,Pneumocystis jirovecii pneumonia in intensive care units: a multicenter study by ESGCIP and EFISG,figshare,2023,,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,0,0,0,0,0,2023-08-25T03:21:17.000Z,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'}]",,,,,['IsIdenticalTo'],"[['IsIdenticalTo', '10.6084/m9.figshare.c.6804540']]"
10.17178/amma-catch.cl.rain_nig,"Precipitation dataset (5 minutes rainfall), 5 stations in Eastern Niger","IRD, CNRS-INSU, OSUG, OMP, OREME",1999,en,Dataset,"Creative Commons Attribution 4.0 International,Data access and use are ruled by the AMMA-CATCH data policy.,For any publication using AMMA-CATCH data, authors are asked to:
Mandatory: cite the reference article and the DOI of the observatory
(1) Galle et al. (2018). AMMA-CATCH a Critical Zone Observatory in West Africa Monitoring a Region in Transition. Vadose Zone Journal, 17 (1), 18006.
(2) AMMA-CATCH (1990). AMMA-CATCH : a hydrological, meteorological and ecological observatory on West Africa. IRD, CNRS-INSU, OSUG, OMP, OREME. doi:10.17178/AMMA-CATCH.all
Optional: cite the DOI of each dataset used.
Co-authorship: depending on the contribution of the data to the scientific results obtained, the authors should either propose co-authorship to the data providers or at least acknowledge their contribution.",Documentation of rainfall in the Sahelian zone. The aim is to characterize the temporal variability of rainfall at regional scales.,mds,True,findable,0,0,1,0,0,2018-03-16T15:37:15.000Z,2018-03-16T15:37:15.000Z,inist.osug,jbru,"Rainfall, precipitation, tropical convection,Sahelian climate,Precipitation Amount (previous 24 hours),Precipitation Amount (previous 5 minutes),Precipitation Amount (previous hour)","[{'subject': 'Rainfall, precipitation, tropical convection', 'subjectScheme': 'main'}, {'subject': 'Sahelian climate', 'subjectScheme': 'main'}, {'subject': 'Precipitation Amount (previous 24 hours)', 'subjectScheme': 'var'}, {'subject': 'Precipitation Amount (previous 5 minutes)', 'subjectScheme': 'var'}, {'subject': 'Precipitation Amount (previous hour)', 'subjectScheme': 'var'}]",,"['CSV', 'NETCDF', 'O&M 1.0']",,,"['Cites', 'IsPartOf', 'IsPartOf']",
10.5281/zenodo.8037001,"Data supporting 'Ice loss in the European Alps until 2050 using a fully assimilated, deep-learning-aided 3D ice-flow model'",Zenodo,2024,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,0,0,0,0,0,2024-01-22T14:00:42.000Z,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'}]",,,,,"['HasVersion', 'HasVersion', 'HasVersion']","[['IsVersionOf', '10.5281/zenodo.8037001']]"
10.5281/zenodo.4738733,Salem simulator 2.0,Zenodo,2021,en,Software,"GNU Library General Public License v2.1 or later,Open Access","Installer for the Salem simulator 2.0, including the source code. This version corresponds to the release r17186 on the Capsis repository (http://capsis.cirad.fr/capsis/home). Java Runtime Environment 1.8.xxx is required to run the simulator. Salem predicts the dynamics of pure and mixed even-aged forest stands and makes it possible to simulate management operations. Its purpose is to be a decision support tool for forest managers and stakeholders as well as for policy makers. It is also designed to conduct virtual experiments and help answer research questions. Salem is essentially calibrated with French National Forest Inventory for 12 common tree species of Eupore. The mixture effect on species growth is assessed for 24 pairs of these species. Salem runs on Windows, Linux, or Mac. Its user-friendly Graphical User Interface makes it easy to use for non-modellers.",mds,True,findable,0,0,0,0,0,2021-10-19T12:00:16.000Z,2021-10-19T12:00:18.000Z,cern.zenodo,cern,"Forest,Simulator,Growth,Mixture effect,Foret management,Silviculture","[{'subject': 'Forest'}, {'subject': 'Simulator'}, {'subject': 'Growth'}, {'subject': 'Mixture effect'}, {'subject': 'Foret management'}, {'subject': 'Silviculture'}]",,,,,"['HasVersion', 'HasVersion']","[['IsVersionOf', '10.5281/zenodo.4738733']]"
10.15778/resif.rd,CEA/DASE broad-band permanent network in metropolitan France,RESIF - Réseau Sismologique et géodésique Français,2018,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,0,0,0,8,0,2018-06-05T15:07:27.000Z,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']",,,,
10.18709/perscido.2017.11.ds185,Sparse Integer Matrices Collection,PerSciDo,2019,en,Dataset,Creative Commons Attribution Share Alike 4.0 International,"Collection of matrices used in exact computations. Most of them are sparse with integral or modular coefficients, some have rational or polynomial entries.",fabrica,True,findable,0,0,0,1,0,2019-03-14T16:33:23.000Z,2019-03-14T16:33:23.000Z,inist.persyval,vcob,"Computer Science,Mathematics,FOS: Mathematics,FOS: Mathematics","[{'lang': 'en', 'subject': 'Computer Science'}, {'lang': 'en', 'subject': 'Mathematics'}, {'subject': 'FOS: Mathematics', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': 'FOS: Mathematics', 'subjectScheme': 'Fields of Science and Technology (FOS)'}]",['5 GB'],['sms'],,,['IsCitedBy'],
10.26302/sshade/experiment_soc_20181115_005,"Fe K edge XAS HERFD (Kbeta1,3) and XES of synthetic maghemite gamma-Fe2O3 at ambient conditions",SSHADE/FAME (OSUG Data Center),2018,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,0,0,0,0,0,2019-12-05T14:22:39.000Z,2019-12-05T14:22:40.000Z,inist.sshade,mgeg,"solid,commercial,homopolymer,Cellulose,laboratory,oxide-hydroxide,Fe2O3,laboratory measurement,fluorescence emission,None,hard X,hard X-rays","[{'subject': 'solid'}, {'subject': 'commercial'}, {'subject': 'homopolymer'}, {'subject': 'Cellulose'}, {'subject': 'laboratory'}, {'subject': 'oxide-hydroxide'}, {'subject': 'Fe2O3'}, {'subject': 'laboratory measurement'}, {'subject': 'fluorescence emission'}, {'subject': 'None'}, {'subject': 'hard X'}, {'subject': 'hard X-rays'}]",['3 spectra'],['ASCII'],,,"['IsPartOf', 'IsPartOf']",
10.6084/m9.figshare.25854589,Additional file 1 of Development and validation of the tic score for early detection of traumatic coagulopathy upon hospital admission: a cohort study,figshare,2024,,Image,Creative Commons Attribution 4.0 International,Supplementary file 1 (JPG 1471 kb),mds,True,findable,0,0,32,0,0,2024-05-19T03:20:59.000Z,2024-05-19T03:20:59.000Z,figshare.ars,otjm,"Medicine,Neuroscience,Biotechnology,Cancer,Science Policy,Mental Health,Hematology,Virology,Computational Biology","[{'subject': 'Medicine'}, {'subject': 'Neuroscience'}, {'subject': 'Biotechnology'}, {'subject': 'Cancer'}, {'subject': 'Science Policy'}, {'subject': 'Mental Health'}, {'subject': 'Hematology'}, {'subject': 'Virology'}, {'subject': 'Computational Biology'}]",['1507079 Bytes'],,,,"['IsIdenticalTo', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References']","[['IsIdenticalTo', '10.6084/m9.figshare.25854589']]"
10.26302/sshade/experiment_zed_20230705_01,NIR reflectance spectra of Mercury minerals analogs cooled up to 148K,SSHADE/DAYSY (OSUG Data Center),2023,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,0,0,2,0,0,2023-07-10T14:20:24.000Z,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'],,,"['IsPartOf', 'IsPartOf', 'IsSourceOf', 'Cites', 'IsSourceOf', 'Cites', 'IsSourceOf', 'Cites']",
10.57745/tvahuq,Long term monitoring of near surface soil temperature in the french Alps part of ORCHAMP observatory,Recherche Data Gouv,2023,,Dataset,,"Monitoring of near-surface soil temperature in seasonaly snow-covered, mountain ecosystems located in the French Alps. Data are part the ORCHAMP project. Data include a GPS position, a date and time in UTC and a near-surface soil temperature (in °C) measured at 5 cm belowground using stand-alone temperature data logger. The first sensors were installed in 2016. Data collection is still in progress and new sites are added every year since 2016.",mds,True,findable,75,11,0,0,0,2023-03-27T14:02:49.000Z,2023-07-18T07:43:40.000Z,rdg.prod,rdg,,,,,,,"['HasPart', 'HasPart', 'HasPart']",
10.5281/zenodo.6104367,Unique and shared effects of local and catchment predictors over distribution of hyporheic organisms: does the valley rule the stream?,Zenodo,2022,,Software,"MIT License,Open Access","This dataset describe the distribution of two hyporheic crustacean taxa (Bogidiellidae, Amphipoda and Anthuridae, Isopoda) in streams of New Caledonia. We sampled the two taxa at 228 sites. At each site, we quantified nine local predictors related to habitat area and stability, sediment metabolism and water origin, and eight catchment predictors related to geology, area, primary productivity, land use and specific discharge.",mds,True,findable,0,0,0,0,0,2022-02-17T19:47:15.000Z,2022-02-17T19:47:16.000Z,cern.zenodo,cern,"spatial scale,hyporheic zone,subterranean crustaceans,New Caledonia,Bogidiellidae,Amphipoda,Anthuridae,Isopoda,local,catchment","[{'subject': 'spatial scale'}, {'subject': 'hyporheic zone'}, {'subject': 'subterranean crustaceans'}, {'subject': 'New Caledonia'}, {'subject': 'Bogidiellidae'}, {'subject': 'Amphipoda'}, {'subject': 'Anthuridae'}, {'subject': 'Isopoda'}, {'subject': 'local'}, {'subject': 'catchment'}]",,,,,"['IsSourceOf', 'HasVersion', 'IsPartOf']","[['IsVersionOf', '10.5281/zenodo.6104367']]"
10.5281/zenodo.5654627,PACT-1D model version including polar halogen emissions - output files,Zenodo,2021,,Dataset,"Creative Commons Attribution 4.0 International,Open Access",This dataset includes all output files created from the PACT-1D model (v1.0) developed with Arctic chlorine and bromine emission parameterizations. The PACT-1D source code used to create these output files is available at: https://doi.org/10.5281/zenodo.5654589.,mds,True,findable,0,0,0,0,0,2021-11-08T14:46:31.000Z,2021-11-08T14:46:32.000Z,cern.zenodo,cern,,,,,,,['HasVersion'],"[['IsVersionOf', '10.5281/zenodo.5654627']]"
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,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,0,0,0,0,0,2023-04-21T07:13:51.000Z,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'],,,"['IsPartOf', 'IsPartOf', 'IsDerivedFrom', 'Cites', 'IsSourceOf', 'Cites', 'IsSourceOf', 'Cites', 'IsDerivedFrom', 'Cites', 'IsSourceOf', 'Cites', 'IsSourceOf', 'Cites']",
10.5281/zenodo.4943233,"Supplementary Data Set for ""Seeds of imperfection rule the mesocrystalline disorder in natural anhydrite single crystals""",Zenodo,2021,,Dataset,"Creative Commons Attribution 4.0 International,Open Access",Complete data sets: 1. DATA_SAXS_WAXS.zip - raw and reduced SAXS and WAXS measurements. NXS format and metadata 2. M-ERSC2020110901CT.zip - raw X-ray microtomography dataset. TIFF format and metadata. 3. Video_1_CT_3D_overview_XY_rotation.avi - uncompressed video 4. Video_2_CT_3D_overview_ZX_rotation.avi - uncompressed video 5. Video_3_CT_3D_internal_structure_XY_rotation.avi - uncompressed video,mds,True,findable,0,0,0,0,0,2021-06-17T05:00:44.000Z,2021-06-17T05:00:46.000Z,cern.zenodo,cern,"calcium sulfate,calcium sulphate,anhydrite,single crystal,mesocrystal,nucleation and growth,crystallisation,particle mediated","[{'subject': 'calcium sulfate'}, {'subject': 'calcium sulphate'}, {'subject': 'anhydrite'}, {'subject': 'single crystal'}, {'subject': 'mesocrystal'}, {'subject': 'nucleation and growth'}, {'subject': 'crystallisation'}, {'subject': 'particle mediated'}]",,,,,"['HasVersion', 'IsPartOf']","[['IsVersionOf', '10.5281/zenodo.4943233']]"
10.5281/zenodo.6793400,Pycorr,Zenodo,2022,,Software,Open Access,"PYCORR v1.0 https://gricad-gitlab.univ-grenoble-alpes.fr/bouep/pycorr/ Python3.7 Ambient seismic noise correlation package Retrieve seismic station information from FDSN catalog : http://service.iris.edu/irisws/fedcatalog/1/ Retrieve waveforms from FDSN-webservices and/or personal archive Basic processing ""on the fly"": decimation, sensor response, gaps... Possible (pre-) processing before correlation Xcorr with flexible parameters for optimized tomography and/or monitoring applications Tensor rotation to retrieve RT information Basic toolbox to extract and plot correlations results from large output",mds,True,findable,0,0,0,0,0,2022-07-04T08:11:39.000Z,2022-07-04T08:11:40.000Z,cern.zenodo,cern,,,,,,,['HasVersion'],"[['IsVersionOf', '10.5281/zenodo.6793400']]"
10.26302/sshade/experiment_bs_20201201_001,"Bidirectional Vis-NIR reflectance spectra of two tholins samples (+ mixtures with pyrrhotite) at various illumination-observation geometries (i=0°,30°,60° - e= -70° to 70°) and their extracted single scattering albedo and optical constants spectra",SSHADE/GhoSST (OSUG Data Center),2021,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.","Bidirectional Vis-NIR reflectance spectra (0.4-2.5 µm) of two tholins samples (99%-N2:1%-CH4:500ppm-CO and 95%-N2:5%-CH4:500ppm-CO) at various illumination-observation geometries (i=0°,30°,60° - e= -70° to 70°, step 10°) and their extracted single scattering albedo and optical constants spectra. Also series of 13 mixtures with pyrrhotite (from 1ppm to 5%)",mds,True,findable,0,0,0,0,0,2021-06-02T08:37:35.000Z,2021-06-02T08:37:36.000Z,inist.sshade,mgeg,"carbonaceous,laboratory,complex macromolecular mixture,Tholins,natural terrestrial,sulfide,Pyrrhotite,laboratory measurement,bidirectional reflection,macroscopic,Vis,Visible,NIR,Near-Infrared,reflectance factor,single scattering albedo,optical constants","[{'subject': 'carbonaceous'}, {'subject': 'laboratory'}, {'subject': 'complex macromolecular mixture'}, {'subject': 'Tholins'}, {'subject': 'natural terrestrial'}, {'subject': 'sulfide'}, {'subject': 'Pyrrhotite'}, {'subject': 'laboratory measurement'}, {'subject': 'bidirectional reflection'}, {'subject': 'macroscopic'}, {'subject': 'Vis'}, {'subject': 'Visible'}, {'subject': 'NIR'}, {'subject': 'Near-Infrared'}, {'subject': 'reflectance factor'}, {'subject': 'single scattering albedo'}, {'subject': 'optical constants'}]",['21 spectra'],['ASCII'],,,"['IsPartOf', 'IsPartOf']",
10.26302/sshade/experiment_lb_20170731_002,MIR absorbance spectra of pressed QUE99177 matrix grains (CR Chondrite) under vacuum at different temperatures,SSHADE/GhoSST (OSUG Data Center),2018,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 (baseline-corrected) MIR absorbance spectra of several matrix grains of QUE99177 (CR Chondrite) pressed on a diamond window and measured under vacuum at ambient temperature (22°C) and after heating at 300°C,mds,True,findable,0,0,0,0,0,2021-05-02T05:47:13.000Z,2021-05-02T05:47:14.000Z,inist.sshade,mgeg,"extraterrestrial,complex organic-mineral mix,matrix QUE99177,physically adsorbed phase,adsorbed water,matrix QUE99177 heated at 300°C,laboratory measurement,transmission,microscopy,MIR,Mid-Infrared,absorbance","[{'subject': 'extraterrestrial'}, {'subject': 'complex organic-mineral mix'}, {'subject': 'matrix QUE99177'}, {'subject': 'physically adsorbed phase'}, {'subject': 'adsorbed water'}, {'subject': 'matrix QUE99177 heated at 300°C'}, {'subject': 'laboratory measurement'}, {'subject': 'transmission'}, {'subject': 'microscopy'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'absorbance'}]",['27 spectra'],['ASCII'],,,"['IsPartOf', 'IsPartOf']",
10.6084/m9.figshare.16851105,Additional file 20 of The mitochondrially-localized nucleoside diphosphate kinase D (NME4) is a novel metastasis suppressor,figshare,2021,,Text,Creative Commons Attribution 4.0 International,Additional file 20: Table S3. Characteristics of the 526 human breast tumor cohort.,mds,True,findable,0,0,93,1,0,2021-10-22T04:05:31.000Z,2021-10-22T04:05:32.000Z,figshare.ars,otjm,"Biophysics,Biochemistry,Medicine,Cell Biology,Genetics,FOS: Biological sciences,Molecular Biology,Physiology,Immunology,FOS: Clinical medicine,Developmental Biology,Cancer,Hematology,Infectious Diseases,FOS: Health sciences,Computational Biology","[{'subject': 'Biophysics'}, {'subject': 'Biochemistry'}, {'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': 'Physiology'}, {'subject': 'Immunology'}, {'subject': 'FOS: Clinical medicine', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': 'Developmental Biology'}, {'subject': 'Cancer'}, {'subject': 'Hematology'}, {'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'}]",['51712 Bytes'],,,,"['References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'IsSupplementTo']",
10.5281/zenodo.4064128,Snow cover in the European Alps: Station observations of snow depth and depth of snowfall,Zenodo,2021,en,Dataset,"Creative Commons Attribution 4.0 International,Open Access","Auxiliary files, code, and data for paper published in The Cryosphere: Observed snow depth trends in the European Alps 1971 to 2019 https://doi.org/10.5194/tc-15-1343-2021 <strong>Auxiliary files:</strong> aux_paper.zip: Auxiliary figures to the paper (time series showing the consistency of averaging monthly mean snow depth of stations within 500 m elevation bins; times of seasonal snow depth and snow cover duration indices). aux_paper_crocus_comparison.zip: Time series comparing spatial statistical gap filling from paper to gap filling using snow depth assimilation into Crocus snow model (only for subset of stations in the French Alps) aux_paper_monthly_time_series.zip: Plots of monthly time series of snow depth, for each station. aux_paper_spatial_consistency.zip: Aggregate results from spatial consistency (statistical simulation using neighboring stations), and time series of observed versus simulated monthly snow depths. <strong>Code </strong>(working copy, not cleaned, all written in R statistical software): code.zip to read in the different data sources to do quality checks and data processing to perform statistical analyses as in paper to produce figures and tables as in paper <strong>Data</strong>: > 2000 stations from Austria, Germany, France, Italy, Switzerland, and Slovenia Daily stations snow depth and depth of snowfall, as .zips, grouped by data provider. Information on column content is provided in ""data_daily_00_column_names_content.txt"". Monthly stations mean snow depth, sum of depth of snowfall, maximum snow depth, days with snow cover (1-100cm thresholds), as .zips, grouped by data provider. Information on column content is provided in ""data_monthly_00_column_names_content.txt"". Meta data (name, latitude, longitude, elevation) in ""meta_all.csv"", along with an interactive map ""meta_interactive_map.html"", and column information in ""meta_00_column_names_content.txt"". If you <strong>use the data you agree to adhere to the respective data provider's terms</strong> as listed in ""00_DATA_LICENSE_AND_TERMS.PDF"" The license terms especially (and additionally to any other terms of the single data providers) include: <strong>Attribution</strong> — You must give appropriate credit, provide a link to the license, and indicate if changes were made. You may do so in any reasonable manner, but not in any way that suggests the licensor endorses you or your use. [from CC BY 4.0] <strong>Version history:</strong> v1.3: added maxHS and SCD (with various 1-100cm thresholds) to monthly data v1.2: uploaded data v1.1: changes to aux-paper.zip and code.zip as consequence from submitting a revised manuscript v1.0: initial upload",mds,True,findable,0,0,0,1,0,2021-07-16T10:47:06.000Z,2021-07-16T10:47:07.000Z,cern.zenodo,cern,,,,,,,"['IsSourceOf', 'HasVersion', 'HasVersion', 'HasVersion', 'HasVersion']","[['IsVersionOf', '10.5281/zenodo.4064128']]"
10.6084/m9.figshare.21550639,Self-compassion and emotion regulation: testing a mediation model,Taylor & Francis,2022,,Text,Creative Commons Attribution 4.0 International,"Self-compassion (SC) seems to play an important role in improving Emotion Regulation (ER). Nevertheless, the results of previous studies regarding the links between SC and ER are not consistent, especially facing diverse models of ER (strategy-based vs skill-based). The goal of this prospective study was to evaluate the links between these three concepts, by testing the predictive roles of SC and ER skills on both ER adaptive and maladaptive strategies, using standardised questionnaires and visual analogue scales. Results of regression analysis showed that self-compassion positively predicts cognitive reappraisal, acceptance, problem-solving, relaxation, self-support, tolerance and ER skills and negatively predicts behavioural avoidance, expressive suppression and ruminations. Results also showed that ER skills positively predict cognitive reappraisal, expression, acceptance, relaxation, self-support and tolerance and negatively predicts behavioural avoidance, expressive suppression and ruminations. Results from a mediation model are also promising regarding both the role of ER skills on the effect of SC on adaptive ER strategy use. Even if this study can be associated with common limits of self-report measures, it highlights the role of SC in a model of ER.",mds,True,findable,0,0,0,0,0,2022-11-14T09:00:05.000Z,2022-11-14T09:00:06.000Z,figshare.ars,otjm,"Medicine,Sociology,FOS: Sociology,69999 Biological Sciences not elsewhere classified,FOS: Biological sciences,Science Policy","[{'subject': 'Medicine'}, {'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'}]",['20085 Bytes'],,,,['IsSupplementTo'],
10.5061/dryad.n230404,Data from: The regulation of emotions in adolescents: age differences and emotion-specific patterns,Dryad,2019,en,Dataset,Creative Commons Zero v1.0 Universal,"Two experiments addressed the issue of age-related differences and
emotion-specific patterns in emotion regulation during adolescence.
Experiment 1 examined emotion-specific patterns in the effectiveness of
reappraisal and distraction strategies in 14-year-old adolescents (N =
50). Adolescents were instructed to answer spontaneously or to
downregulate their responses by using either distraction or cognitive
reappraisal strategies before viewing negative pictures and were asked to
rate their emotional state after picture presentation. Results showed that
reappraisal effectiveness was modulated by emotional content but
distraction was not. Reappraisal was more effective than distraction at
regulating fear or anxiety (threat-related pictures) but was similar to
distraction regarding other emotions. Using the same paradigm, Experiment
2 examined in 12-year-old (N = 56), 13-year-old (N = 49) and 15-year-old
adolescents (N = 54) the age-related differences a) in the effectiveness
of reappraisal and distraction when implemented and b) in the everyday use
of regulation strategies using the Cognitive Emotion Regulation
Questionnaire. Results revealed that regulation effectiveness was
equivalent for both strategies in 12-year-olds, whereas a large
improvement in reappraisal effectiveness was observed in 13- and
15-year-olds. No age differences were observed in the reported use of
reappraisal, but older adolescents less frequently reported using
distraction and more frequently reported using the rumination strategy.
Taken together, these experiments provide new findings regarding the use
and the effectiveness of cognitive regulation strategies during
adolescence in terms of age differences and emotion specificity.",mds,True,findable,391,58,1,1,0,2018-03-29T07:56:34.000Z,2018-03-29T07:56:35.000Z,dryad.dryad,dryad,"distraction,Adolescents,reappraisal","[{'subject': 'distraction'}, {'subject': 'Adolescents', 'schemeUri': 'https://github.com/PLOS/plos-thesaurus', 'subjectScheme': 'PLOS Subject Area Thesaurus'}, {'subject': 'reappraisal'}]",['119040 bytes'],,,,['IsCitedBy'],
10.5281/zenodo.10652455,TDP-43 motifs in the GISAID Database v1.0.0-alpha,Zenodo,2024,,Software,MIT License,"TDP-43 motifs in the GISAID Database - Version v1.0.0-alpha
This repository contains Python scripts that automate the process of downloading, merging, and processing data from the GISAID website. The scripts are organized into two directories: `GISAID-crawler` and `TDP-43`, each with its own README file detailing the specific operations performed by the scripts within.
Details
Please refer to each script code to install the appropriate packages via pip3. The scripts are run using Python 3.10.0. Be situated on each working directory to execute the script. Refer to each README file for more information.
Disclaimer: in order to access the information in the GISAID database you must have your own access by creating a username and being given a password. In these scripts, I did not include any data contained in the database, in accordance with the GISAID terms and conditions. This data has not been shared to anyone nor cross-examined with any other influenza database. A separate table acknowledging all sources of the original data will be added.
License
This software is released under the MIT License.
Acknowledgments
Freunde von GISAID and all the researchers that deposited their sequences in their database. Nadia Naffakh for the cannonical sequences max and min sizes and discussion. Darren Hart for discussion.",api,True,findable,0,0,0,0,1,2024-02-13T01:00:52.000Z,2024-02-13T01:00:53.000Z,cern.zenodo,cern,"influenza,TDP-43,GISAID","[{'subject': 'influenza'}, {'subject': 'TDP-43'}, {'subject': 'GISAID'}]",,,,,"['IsSupplementTo', 'HasVersion']",
10.34847/nkl.4540o25d,"Public space geopositionned ethnographic observations for the sites Quai de plantes, Jardin extraordinaire, Rideau place Graslin, Estrade rafraichissante, Ilot frais and Parc of La Defense",NAKALA - https://nakala.fr (Huma-Num - CNRS),2023,en,Dataset,,"Jeu de données géospatialisées concernant les campagnes d'observation des usages dans le cadre du projet ANR Coolscapes.
Campagnes d'enquête réalisées dans les étés 2020 et 2021 sur six sites : Quai des plantes (Nantes, 2020), Jardin extraordinaire (Nantes, 2020), Place Graslin avec installation Rideau sur la façade de l'opéra (Nantes, 2020), Estrade rafraîchissante sur le parvis de La Défense (Paris, 2021), Ilot frais skycooling sur le parvis de La Défense (Paris, 2021) et Parc de l'Axe de La Défense (Paris, 2021).
Pour chaque site et année d'enquête, il y a 4 fichiers :
- site_ville_année_moving.gpkg : données correspondants aux flux de déplacements des citadins sur format Geopackage (CRS 2154).
- site_ville_année_moving.csv : idem sans géolocalisation en format Comma separated values à des fins statiques.
- site_ville_année_static.gpkg : données correspondants aux lieux d'activités à l'arrêt des citadins sur format Geopackage (CRS 2154).
- site_ville_année_static.csv : idem sans géolocalisation en format Comma separated values à des fins statiques.
Chaque entité observée est une cellule d'activité, qu'elle soit composée d'une personne ou de plusieurs.
Chaque entité a été renseignée selon les attributs suivant :
- site : appellation du site
- survey_id : identification de l'enquête
- row_id : identification de l'entité
- obs_type : type d'observation
- timestamp : horodatage de l'entité en GMT +1 (Paris)
- date : date
- time : heure
- X_lb93 et Y_lb93 : coordonnées spatiales en projection CRS 2154 Lambert-93, ceci est seulement renseigné pour les observations statiques.
- X_wgs84 et Y_wgs84 : coordonnées spatiales en projection CRS 4326 WGS84, ceci est seulement renseigné pour les observations statiques.
- row_total : nombre total de personnes intégrant la cellule observée.
- gender_male : nombre d'hommes
- gender_female : nombre de femmes
- age_mean : âge moyen calculé selon le nombre de personnes par tranche d'âge ci-dessous
- age_0_7 : nombre de personnes avec un âge perçu entre 0 et 7 ans (selon l'enquêteur)
- age_8_17 : nombre de personnes avec un âge perçu entre 8 et 17 ans (selon l'enquêteur)
- age_18_34 : nombre de personnes avec un âge perçu entre 18 et 34 ans (selon l'enquêteur)
- age_35_50 : nombre de personnes avec un âge perçu entre 35 et 50 ans (selon l'enquêteur)
- age_51_64 : nombre de personnes avec un âge perçu entre 51 et 64 ans (selon l'enquêteur)
- age_65 : nombre de personnes avec un âge perçu supérieur à 65 ans (selon l'enquêteur)
- posture : posture du corps prédominante dans la cellule (Tsay and Andersen, 2017)
- engagement : forme d'interaction avec l'espace et l'effet rafraîchissant supposé dans l'espace
- clothing : dégrée d'habillement (selon Fanger 1974)
- exposure : exposition au soleil
- activity : activité (Tsay and Andersen, 2017)
- stay_time : temps de séjours perçu par l'enquêteur (les entités en déplacement sont par défaut entre 0 et 2 minutes)
- geometry : identification des coordonnées de la géométrie spatiale.",api,True,findable,0,0,0,0,0,2023-04-14T15:03:47.000Z,2023-04-14T15:03:47.000Z,inist.humanum,jbru,"observation passive,rafraîchissement urbain,ethnographie urbaine,Espace public,urban ethnography,Public spaces,passive activity observation,urban cooling","[{'lang': 'fr', 'subject': 'observation passive'}, {'lang': 'fr', 'subject': 'rafraîchissement urbain'}, {'lang': 'fr', 'subject': 'ethnographie urbaine'}, {'lang': 'fr', 'subject': 'Espace public'}, {'lang': 'en', 'subject': 'urban ethnography'}, {'lang': 'en', 'subject': 'Public spaces'}, {'lang': 'en', 'subject': 'passive activity observation'}, {'lang': 'en', 'subject': 'urban cooling'}]","['204800 Bytes', '93258 Bytes', '299008 Bytes', '114155 Bytes', '221184 Bytes', '105863 Bytes', '131072 Bytes', '16589 Bytes', '225280 Bytes', '105233 Bytes', '278528 Bytes', '85698 Bytes', '118784 Bytes', '20414 Bytes', '114688 Bytes', '8580 Bytes', '118784 Bytes', '17355 Bytes', '163840 Bytes', '35876 Bytes', '143360 Bytes', '33617 Bytes', '122880 Bytes', '13864 Bytes']","['application/x-sqlite3', 'application/csv', 'application/x-sqlite3', 'application/csv', 'application/x-sqlite3', 'application/csv', 'application/x-sqlite3', 'application/csv', 'application/x-sqlite3', 'application/csv', 'application/x-sqlite3', 'application/csv', 'application/x-sqlite3', 'application/csv', 'application/x-sqlite3', 'application/csv', 'application/x-sqlite3', 'application/csv', 'application/x-sqlite3', 'application/csv', 'application/x-sqlite3', 'application/csv', 'application/x-sqlite3', 'application/csv']",,,,
10.5281/zenodo.10650736,Combining Loop Shuffling and Code Polymorphism for Enhanced AES Side-Channel Security,Zenodo,2024,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,0,0,0,0,0,2024-02-12T14:54:51.000Z,2024-02-12T14:54:51.000Z,cern.zenodo,cern,,,,,,,['HasVersion'],"[['IsVersionOf', '10.5281/zenodo.10650736']]"
10.5281/zenodo.7970337,"CliffEBM - A Gridded Ice Cliff Energy Balance Model (first public release, v01.1)",Zenodo,2023,en,Software,Creative Commons Attribution 4.0 International,"CliffEBM is a model that calculates the distributed surface energy balance and backwasting (melt) rates for ice cliffs, i.e. steep ice surfaces with complex, heterogeneous topographies. The model is validated and described in
Buri, P., Pellicciotti, F., Steiner, J., Miles, E., & Immerzeel, W. (2016). A grid-based model of backwasting of supraglacial ice cliffs on debris-covered glaciers. Annals of Glaciology, 57(71), 199-211. https://doi.org/10.3189/2016AoG71A059
See most update version here: https://github.com/pburi/CliffEBM
In this repository we provide example input data (digital elevation models, shapefiles, meteodata) to run CliffEBM on one supraglacial cliff on the debris-covered Lirung Glacier (Nepal).
Working example: to run the model, download the entire repository on your machine and adjust the paths in the model code (CliffEBM.R, section ""primary definitions"") according to the paths on your machine.
Software: R (R version 4.3.0 (2023-04-21 ucrt) -- ""Already Tomorrow""). The model should also run on older versions.
Packages: cleaRskyQuantileRegression, doParallel, foreach, grDevices, iterators, methods, parallel, raster, rgdal, rgeos, sf, sp, stats, utils, zoo",mds,True,findable,0,0,0,0,0,2023-05-25T11:41:22.000Z,2023-05-25T11:41:22.000Z,cern.zenodo,cern,"Ice cliffs,Debris-covered glaciers,Energy balance,Backwasting","[{'subject': 'Ice cliffs'}, {'subject': 'Debris-covered glaciers'}, {'subject': 'Energy balance'}, {'subject': 'Backwasting'}]",,,,,"['IsPublishedIn', 'IsDerivedFrom', 'HasVersion']","[['IsVersionOf', '10.5281/zenodo.7970337']]"
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,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,0,0,0,0,0,2019-12-13T13:04:26.000Z,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'],,,"['IsPartOf', 'IsPartOf', 'IsPartOf', 'IsSourceOf']",
10.6084/m9.figshare.25284801,Additional file 1 of Intra-breath changes in respiratory mechanics are sensitive to history of respiratory illness in preschool children: the SEPAGES cohort,figshare,2024,,Text,Creative Commons Attribution 4.0 International,Supplementary Material 1,mds,True,findable,0,0,0,0,0,2024-02-25T04:40:03.000Z,2024-02-25T04:40:04.000Z,figshare.ars,otjm,"Medicine,Genetics,FOS: Biological sciences,Sociology,FOS: Sociology,Cancer,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': 'Sociology'}, {'subject': 'FOS: Sociology', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': 'Cancer'}, {'subject': 'Science Policy'}]",['58940 Bytes'],,,,"['IsIdenticalTo', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References']","[['IsIdenticalTo', '10.6084/m9.figshare.25284801']]"
10.5281/zenodo.4628244,HPL (modified for Simgrid/SMPI),Zenodo,2021,,Software,"BSD licenses (New and Simplified),Open Access","This is a modified version of High Performance Linpack, intended to be used on top Simgrid/SMPI simulator.",mds,True,findable,0,0,1,0,0,2021-03-22T19:58:34.000Z,2021-03-22T19:58:35.000Z,cern.zenodo,cern,,,,,,,"['IsSupplementTo', 'HasVersion']","[['IsVersionOf', '10.5281/zenodo.4628244']]"
10.6084/m9.figshare.21430974,Additional file 2 of Digitally-supported patient-centered asynchronous outpatient follow-up in rheumatoid arthritis - an explorative qualitative study,figshare,2022,,Text,Creative Commons Attribution 4.0 International,Supplementary Material 2,mds,True,findable,0,0,0,0,0,2022-10-29T03:17:13.000Z,2022-10-29T03:17:14.000Z,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)'}]",['14460 Bytes'],,,,['IsSupplementTo'],
10.26302/sshade/bandlist_raman_spherocobaltite,Raman bandlist of natural Spherocobaltite,SSHADE/BANDLIST (OSUG Data Center),2023,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 Spherocobaltite at 295K,mds,True,findable,0,0,2,0,0,2023-08-12T14:39:57.000Z,2023-08-12T14:39:58.000Z,inist.sshade,mgeg,"Spherocobaltite,Cobaltous cation,Carbonate anion,Cobalt(2+) cation,22541-53-3,Co2+,(CO3)2-,CoCO3,Spherocobaltite,non-silicate mineral,carbonate,carbonates, nitrates, borates,anhydrous carbonates,Calcite group (Trigonal: R-3c),14.01.01.05,05.AB.05,Raman scattering,FIR,MIR,band frequency,band width,band intensity,transition and vibration modes","[{'subject': 'Spherocobaltite', 'subjectScheme': 'name'}, {'subject': 'Cobaltous cation', 'subjectScheme': 'name'}, {'subject': 'Carbonate anion', 'subjectScheme': 'name'}, {'subject': 'Cobalt(2+) cation', 'subjectScheme': 'IUPAC name'}, {'subject': '22541-53-3', 'subjectScheme': 'CAS number'}, {'subject': 'Co2+', 'subjectScheme': 'formula'}, {'subject': '(CO3)2-', 'subjectScheme': 'formula'}, {'subject': 'CoCO3', 'subjectScheme': 'formula'}, {'subject': 'Spherocobaltite', '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': '14.01.01.05', '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'],,,"['IsPartOf', 'IsPartOf', 'IsDerivedFrom', 'Cites', 'IsSourceOf', 'Cites', 'IsSourceOf', 'Cites']",
10.57745/b6psx0,Speckle-correlation imaging through a kaleidoscopic multimode fiber (experimental data and Python scripts),Recherche Data Gouv,2023,,Dataset,,"Data set of the paper : ""Speckle-correlation imaging through a kaleidoscopic multimode fiber"". This includes the intensity correlation function of the excitation field for the 10.5 cm long fiber, and the measured signal autocorrelation functions for this fiber under dynamic perturbations.",mds,True,findable,178,32,0,0,0,2023-06-05T15:31:34.000Z,2023-06-15T14:51:30.000Z,rdg.prod,rdg,,,,,,,"['HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart']",
10.5061/dryad.b2rbnzsp7,Data from: Camera traps reveal seasonal variation in activity and occupancy of the Alpine mountain hare (Lepus timidus varronis),Dryad,2024,en,Dataset,Creative Commons Zero v1.0 Universal,"Mountain hare is a cold-adapted species threatened by climate change, but
despite its emblematic nature, our understanding of the causes of
population decline remains limited. Camera traps are increasingly used in
ecology as a tool for monitoring animal populations at large spatial and
temporal scales. In mountain environments where field work is constrained
by difficult access and harsh conditions, camera traps constitute a
promising tool for surveying rare and elusive species such as the mountain
hare. Our study explored the use of camera traps as a tool for studying
seasonal habitat occupancy and daily activity patterns of the mountain
hare, in order to carry out long-term monitoring of populations. We
installed 46 camera traps along elevation gradients in the Mont-Blanc
massif (France) from January 2018 to June 2022. We measured habitat
variables at each camera trap site in order to define vegetation
composition and habitat structure. We performed multi-season and
single-season occupancy models to respectively describe habitat occupancy
of the mountain hare throughout the year and identify the environmental
variables influencing mountain hare presence during the breeding season.
Mountain hares occupy coniferous forest in winter, and then switch to
mixed areas of shrubland and grassland above treeline in spring and the
beginning of summer. In spring, occupancy probability of the mountain hare
increases with relative cover of mixed low shrub and herbaceous layer
(i.e. the 10-40 cm vegetation layer), suggesting a link to food resources
and protection from predation. Our results also confirm the nocturnal and
crepuscular activity of the mountain hare during the breeding season, and
strictly nocturnal activity in winter. Our results demonstrate the
efficiency of camera traps as tools for monitoring mountain hare habitat
occupancy in mountain environments and underline the importance of diverse
habitat mosaics for the preservation of the species.",mds,True,findable,0,0,0,0,0,2024-02-07T20:21:15.000Z,2024-02-07T20:21:16.000Z,dryad.dryad,dryad,"FOS: Natural sciences,FOS: Natural sciences,mountain hare,Camera traps,altitudinal migration,habitat,occupancy,Activity pattern","[{'subject': 'FOS: Natural sciences', 'subjectScheme': 'fos'}, {'subject': 'FOS: Natural sciences', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': 'mountain hare'}, {'subject': 'Camera traps'}, {'subject': 'altitudinal migration'}, {'subject': 'habitat'}, {'subject': 'occupancy'}, {'subject': 'Activity pattern'}]",['1103297 bytes'],,,,,
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,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,0,0,0,0,0,2020-02-11T11:13:50.000Z,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'],,,"['IsPartOf', 'IsPartOf', 'IsSourceOf']",
10.5281/zenodo.10341148,Chamois-CompCert with security features described in Monniaux / CPP 2024,Zenodo,2023,en,Software,INRIA Non-Commercial License Agreement,,api,True,findable,0,0,0,0,0,2023-12-10T18:08:44.000Z,2023-12-10T18:08:44.000Z,cern.zenodo,cern,"formally-verified compiler,Coq,software security,canaries,pointer authentication,CompCert,buffer overflow,tail-recursion elimination,compiler optimizations","[{'subject': 'formally-verified compiler'}, {'subject': 'Coq'}, {'subject': 'software security'}, {'subject': 'canaries'}, {'subject': 'pointer authentication'}, {'subject': 'CompCert'}, {'subject': 'buffer overflow'}, {'subject': 'tail-recursion elimination'}, {'subject': 'compiler optimizations'}]",,,,,"['IsDescribedBy', 'HasVersion']",
10.26302/sshade/experiment_lb_20140114_001,Raman spectra (λ = 514 nm) of matrix grains of CV meteorites,SSHADE/GhoSST (OSUG Data Center),2018,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,0,0,0,0,0,2020-01-31T15:00:53.000Z,2020-01-31T15:00:53.000Z,inist.sshade,mgeg,"extraterrestrial,complex organic-mineral mix,matrix Allende,matrix Axtell,matrix Kaba,matrix Mokoia,matrix Vigarano,matrix Leoville,matrix Efremovka,matrix Bali,laboratory measurement,Raman scattering,microscopy,MIR,Mid-Infrared,Raman scattering intensity,normalized Raman scattering intensity","[{'subject': 'extraterrestrial'}, {'subject': 'complex organic-mineral mix'}, {'subject': 'matrix Allende'}, {'subject': 'matrix Axtell'}, {'subject': 'matrix Kaba'}, {'subject': 'matrix Mokoia'}, {'subject': 'matrix Vigarano'}, {'subject': 'matrix Leoville'}, {'subject': 'matrix Efremovka'}, {'subject': 'matrix Bali'}, {'subject': 'laboratory measurement'}, {'subject': 'Raman scattering'}, {'subject': 'microscopy'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'Raman scattering intensity'}, {'subject': 'normalized Raman scattering intensity'}]",['16 spectra'],['ASCII'],,,"['IsPartOf', 'IsPartOf', 'IsSourceOf']",
10.5281/zenodo.4591773,Data from the IRAM-30m Large Program `Astrochemical Surveys At IRAM' (ASAI),Zenodo,2021,en,Dataset,"Creative Commons Attribution 4.0 International,Open Access","Dataset for the ASAI IRAM-30m Large Program (https://www.iram-institute.org/EN/content-page-344-7-158-240-344-0.html) provided in zenodo within the framework of ACO (AstroChemical Origins): (H2020 MSCA ITN, GA:811312) The reference article is Lefloch et al. 2018, Monthly Notices of the Royal Astronomical Society, Volume 477, Issue 4, p.4792-4809 whose doi is: 10.1093/mnras/sty937 Fully reduced spectral line surveys are included for 10 young stellar objects. SOURCE SAMPLE: <br> ----------------------------------------------------------------------------------------------------------------<br> Sources alpha(2000) delta(2000) rms rms rms dnu Comment <br> (3mm) (2mm) (1.3mm) kHz<br> ----------------------------------------------------------------------------------------------------------------<br> L1544 05h04m17.2s 25d10'42.8"" 2.1-7.0 - - 48.8 Evolved prestellar core<br> TMC1 04h41m41.9s 25d41'27.1"" 3.0-6.3 4.2-4.2 - 48.8, 195.3 Early prestellar core<br> B1 03h33m20.8s 31d07'34.0"" 2.5-10.6 4.4-8.0 4.2-4.6 195.3 First hydrostatic core<br> IRAS4A 03h29m10.4s 31d13'32.2"" 2.5-3.4 5.0-6.1 4.6-3.9 195.3 Class 0: Hot corino prototype<br> L1527 04h39m53.9s 26d03'11.0"" 2.1-6.7 4.2-7.1 4.6-4.1 195.3 Class 0: WCCC prototype<br> L1157mm 20h39m06.3s 68d02'15.8"" 3.0-4.7 5.0-6.5 3.8-3.5 195.3 Class 0: WCCC<br> SVS13A 03h29m03.7s 31d16'03.8"" 2.0-4.8 4.2-5.1 4.6-4.3 195.3 Class I: Hot corino<br> AB Aur 04h55m45.8s 30d33'33.0"" 4.6-4.3 4.8-3.9 2.1-4.3 195.3 Protoplanetary disk<br> L1448-R2 03h25m40.1s 30d43'31.0"" 2.8-4.9 6.0-9.7 2.9-4.9 195.3 Outflow shock spot<br> L1157-B1 20h39m10.2s 68d01'10.5"" 1.1-2.9 4.6-7.2 2.1-4.2 195.3 Outflow shock spot<br> ------------------------------------------------------------------------------------------------------------------<br> i)spectral coverage, spectral resolution, and range of rms noise achieved in an element of 1 km/s for each spectral window. <br> The rms values (in TA*) are measured in the range 86-87 GHz and 113-114 GHz at 3mm, 132-133 GHz and 169-170 GHz at 2mm, <br> 220-221 and 260-261 GHz.<br> ii) No data were obtained at 2mm and 1.3mm for L1544, at 3mm and 1.3mm for TMC1. <br> iii) Complementary observations in the band 72-80 GHz have been obtained for L1544 and protostars IRAS4A, L1527, L1157mm, <br> SVS13A. The 72-80 GHz and 106-115 GHz data of L1544 will be made available in a forthcoming release<br> iv) The data of AB Aur will be made available in a forthcoming release <br> OBSERVATIONS AND SPECTRAL COVERAGE:<br> Details about the observing procedure and the calibration can be found in the article presenting ASAI: ""Astrochemical evolution <br> along star formation: Overview of the IRAM Large Program ASAI"" (Lefloch, Bachiller et al. 2017). L1544 80.0 - 106.0 GHz TMC1 130.0 - 164.9 GHz ; gap from 161.6 to 163.0 GHz Barnard1 80.5 - 112.2 GHz <br> 130.0 - 172.7 GHz <br> 200.5 - 276.0 GHz IRAS4A 71.7 - 79.6 GHz <br> 80.5 - 112.3 GHz <br> 125.5 - 133.3 GHz <br> 130.0 - 172.8 GHz <br> 200.5 - 276.0 GHz L1527 71.7 - 79.6 GHz <br> 80.5 - 112.3 GHz <br> 125.5 - 133.3 GHz <br> 130.0 - 172.8 GHz <br> 200.5 - 276.0 GHz L1157mm 71.7 - 79.6 GHz <br> 80.5 - 112.3 GHz <br> 125.5 - 133.3 GHz <br> 130.0 - 172.8 GHz <br> 200.5 - 276.0 GHz SVS13A 71.7 - 79.6 GHz <br> 80.5 - 116.0 GHz <br> 125.5 - 133.3 GHz <br> 130.0 - 172.8 GHz <br> 200.5 - 276.0 GHz L1448-R2 80.5 - 116.0 GHz <br> 130.0 - 173.3 GHz <br> 200.5 - 276.0 GHz <br> L1157-B1 71.7 - 79.5 GHz <br> 78.0 - 118.0 GHz; fts 390 kHz res;<br> 125.5 - 133.3 GHz <br> 128.2 - 173.7 GHz <br> 200.2 - 265.5 GHz; fts 781 kHz res;<br> 260.4 - 322.1 GHz; WILMA 2 MHz res: <br> 328.4 - 350.1 GHz; WILMA 2 MHz res; The data obtained for each source are located in the corresponding subdirectory: <br> source_f1_f2.fits : calibrated spectral band in the band f1 - f2 (in GHz) <br> source_72_80.fits : complementary data in the bands 72-80 GHz whenever observed. <br> source_125_133.fits : complementary data in the band 125.5-133.5 whenever observed. <br> UNITS:<br> The line intensity are expressed in units of antenna temperature corrected for atmospheric attenuation and the coupling with <br> the sky, TA*, by default. The interested user should to the IRAM webpage http://www.iram.es/IRAMES/mainWiki/Iram30mEfficiencies <br> to convert line intensities from antenna to main-beam temperature scale. <br> QUESTIONS and ACKNOWLEDGMENTS<br> If you have any questions about the data please contact us<br> (bertrand.lefloch@univ-grenoble-alpes.fr, r.bachiller@oan.es). We also like to hear about any<br> scientific use of the data and would appreciate acknowledgment in<br> publications or talks using the ASAI data. <br>",mds,True,findable,0,0,0,0,0,2021-03-10T10:28:31.000Z,2021-03-10T10:28:32.000Z,cern.zenodo,cern,"astrochemistry, protostars, star-forming regions, prestellar cores, radio-astronomy","[{'subject': 'astrochemistry, protostars, star-forming regions, prestellar cores, radio-astronomy'}]",,,,,"['HasVersion', 'IsPartOf']","[['IsVersionOf', '10.5281/zenodo.4591773']]"
10.26302/sshade/experiment_op_20200212_001,Vis-NIR bidirectional reflection spectra of several ammonium salts mixed with graphite powder at 296 K,SSHADE/GhoSST (OSUG Data Center),2020,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.","Mixtures of graphite powder (<20 µm) and ammonium (NH4+) salts (chloride, sulfate, formate) were prepared by mixing manually these constituents in a mortar. Reflectance spectra (from 0.4 to 4 µm) of these mixtures were measured at 296 K under ambient air.",mds,True,findable,0,0,0,0,0,2020-02-12T11:12:11.000Z,2020-02-12T11:12:11.000Z,inist.sshade,mgeg,"mineral,commercial,elemental solid,Graphite,sulfate,Ammonium sulfate,organic salt,Ammonium formate,chloride,Ammonium chloride,laboratory measurement,bidirectional reflection,macroscopic,Vis,Visible,NIR,Near-Infrared,reflectance factor","[{'subject': 'mineral'}, {'subject': 'commercial'}, {'subject': 'elemental solid'}, {'subject': 'Graphite'}, {'subject': 'sulfate'}, {'subject': 'Ammonium sulfate'}, {'subject': 'organic salt'}, {'subject': 'Ammonium formate'}, {'subject': 'chloride'}, {'subject': 'Ammonium chloride'}, {'subject': 'laboratory measurement'}, {'subject': 'bidirectional reflection'}, {'subject': 'macroscopic'}, {'subject': 'Vis'}, {'subject': 'Visible'}, {'subject': 'NIR'}, {'subject': 'Near-Infrared'}, {'subject': 'reflectance factor'}]",['4 spectra'],['ASCII'],,,"['IsPartOf', 'IsPartOf', 'IsSourceOf']",
10.5281/zenodo.10693937,Conception et optimisation d'un réacteur de type MSFR en sels chlorures et en cycle uranium,Zenodo,2024,fr,Text,Creative Commons Attribution 4.0 International,"Depuis le début des années 2000 et suite à la loi Bataille en France, l’équipe MSFR du LPSC de Grenoble a repris le concept des réacteurs à sels fondus, donnant progressivement forme au Molten Salt Fast Reactor (MSFR) de référence. Ce surrégénérateur de 3GWth utilise des sels à base fluor et le cycle thorium. Dans l’optique de proposer un modèle plus à même d’utiliser les matières disponibles (uranium appauvri et noyaux lourds des combustibles usés), cette thèse porte sur l’étude d’un MSFR en cycle uranium.Pour s’affranchir d’éventuels problèmes de solubilité des transuraniens (TRU) en sels fluorures, le sel combustible retenu est un mélange eutectique NaCl-appUCl3-(TRU)Cl3. Ce sel étant un moins bon caloporteur et plus transparent aux neutrons que son équivalent du MSFR fluorure de référence, les travaux de thèse ont d’abord porté sur des études du volume optimal de sel combustible, qui a été porté de 18m3 (MSFR de référence) à 45m3 (MSFR-Cl). Un volume de 20m3 se trouve dans le coeur (optimisation neutronique) et 25m3 sont dans les boucles de recirculation contenant les échangeurs de chaleur (optimisation thermique). Pour améliorer le facteur de régénération du réacteur, une couverture fertile radiale est placée autour de la zone centrale. La composition du sel fertile résulte d’une optimisation principalement entre le débit de retraitement et la résistance à la prolifération. Les études de conception effectuées durant la thèse incluent le dimensionnement des protections neutroniques en tenant compte de la circulation des précurseurs de neutrons retardés, et du vase d’expansion dédié à accommoder la dilatation du sel combustible.Pour tirer un maximum de bénéfices de la forme liquide des sels, le réacteur peut être connecté à une unité de traitement. L’extraction régulière des produits de fission permet ainsi de réduire le terme source et les processus de corrosion tout en améliorant l’économie neutronique, et ce sans besoin d’arrêt du réacteur. Un schéma de principe du traitement envisagé a été conçu durant la thèse en collaboration avec des experts en chimie.Des calculs neutroniques statiques puis en évolution ont été réalisés avec divers codes neutroniques (MCNP couplé au code d’évolution REM, Serpent2) pour évaluer les performances du système (contre-réactions, bilans massiques). Des études préliminaires de déploiement de ce type de réacteurs ont été menées pour évaluer l’impact de l’insertion du MSFR-Cl dans un parc de REP, en comparaison du MSFR de référence.Pour finir, et suite aux limites rencontrées avec le MSFR-Cl, un modèle innovant d'incinérateur de petite taille en cycle uranium à couverture fertile thoriée a été étudié, pour proposer un outil de transition du cycle uranium vers le cycle thorium.",api,True,findable,0,0,0,0,1,2024-02-22T16:13:43.000Z,2024-02-22T16:13:43.000Z,cern.zenodo,cern,,,,,,,['HasVersion'],
10.5281/zenodo.1009121,Esa Seom-Ias – Measurement Database 2.3 Μm Region,Zenodo,2017,,Dataset,"Creative Commons Attribution Share-Alike 4.0,Open Access","The database contains measurements performed within the framework of the esa project SEOM-IAS (Scientific Exploitation of Operational Missions - Improved Atmospheric Spectroscopy Databases), ESA/AO/1-7566/13/I-BG. Details on the project can be found at http://www.wdc.dlr.de/seom-ias/.
Measurements for retrieval of absorption line parameters of H<sub>2</sub>O, CO and CH<sub>4</sub> in the spectral range 4190-4340 cm<sup>-1</sup> within the esa project SEOM-IAS were performed by means of Fourier-Transform Spectroscopy (FTS) at the German Aerospace Center (DLR) and Continuous Wave Cavity Ring-Down Spectroscopy (CRDS) at Université Grenoble Alpes. The aim of the measurements was an improved line parameter database according to the needs of the TROPOMI instrument aboard the Sentinel 5-P satellite. The database contains all used molecular spectra used for Parameter retrieval.",,True,findable,0,0,0,1,0,2017-10-11T14:59:37.000Z,2017-10-11T14:59:38.000Z,cern.zenodo,cern,,,,,,,['HasVersion'],"[['IsVersionOf', '10.5281/zenodo.1009121']]"
10.25364/19.2022.7.3,La comparaison dans Philandre (1544) Procédures figuratives en contexte narratif,Universität Graz,2022,fr,Text,Creative Commons Attribution 4.0 International,"La comparaison participe à l'élaboration des types de texte en s'adaptant aux contraintes formelles
des genres et aux principes de la production des discours, qui évoluent dans le temps. Elle joue en
l'occurrence plusieurs rôles dans l'élaboration des séquences narratives de Philandre, un roman de
chevalerie composé par Jean des Gouttes et publié en 1544. Une double approche de linguistique
textuelle et de stylistique historique permet d'identifier trois grandes procédures figuratives à
l'oeuvre dans les énoncés comparatifs de ces passages, qui méritent une description et une analyse.
La première consiste dans l'expression du haut degré des propriétés qui fondent la ressemblance, la
seconde dans la recherche de précision dans l'identification de celles-ci et la troisième dans l'évaluation
des éléments rapprochés et de l'acte de comparaison",fabricaForm,True,findable,0,0,0,0,0,2022-04-04T09:30:40.000Z,2022-04-04T09:30:41.000Z,ugraz.unipub,ugraz,,,,,,,['IsPartOf'],
10.6084/m9.figshare.c.6077710,Ten actions to achieve gender equity among intensivists: the French Society of Intensive Care (FICS) model,figshare,2022,,Collection,Creative Commons Attribution 4.0 International,"Abstract In our recent survey, we aimed to collect information on perceived inequity as well as professional and personal fulfillment among women intensivists in France. For the 371 respondents out of the 732 persons who received the survey, the findings were unequivocal: for one-third of the respondents, being a woman was considered as an obstacle to careers or academic advancement, and for two thirds, pregnancy was viewed as a barrier to their career advancement. Gender discrimination had been experienced by 55% of the respondents. In 2019, to promote and achieve gender equity in the French Intensive Care Society (FICS), ten actions were initiated and are detailed in the present manuscript together with supporting data: (1) creation of a working group: the FEMMIR group; (2) promotion of mentorship; (3) implementation of concrete sponsorship; (4) transparency and public reporting of gender ratios in editorial boards; (5) workshops dedicated to unconscious gender bias; (6) workshops dedicated to improved women assertiveness; (7) role models; (8) creation of educational/information programs for young intensivists; (9) development of research on gender inequity and, as a perspective; and (10) development of a wide-ranging program. This review is aimed at providing a toolbox of organizational best practices designed to achieve gender equity. It is particularly important to share promising practical action engaged in our FEMMIR group with other concerned professionals around the world.",mds,True,findable,0,0,0,0,0,2022-07-04T09:24:16.000Z,2022-07-04T09:24:18.000Z,figshare.ars,otjm,"Biotechnology,Biological Sciences not elsewhere classified,Science Policy,Mental Health","[{'subject': 'Biotechnology'}, {'subject': 'Biological Sciences not elsewhere classified'}, {'subject': 'Science Policy'}, {'subject': 'Mental Health'}]",,,,,,
10.60527/z64w-t441,"La médiatisation comme enjeu au sein des pratiques, stratégies et dispositifs d’information et de communication politique en ligne","Univ. Grenoble Alpes, GRESEC",2015,fr,Audiovisual,Droit commun de la propriété intellectuelle,"Intervention de Simon GADRAS : ELICO, Université Lumière-Lyon 2. Le 5 mai 2015 à l'Institut de la Communication et des Médias (Université Stendhal Grenoble 3). Communication au colloque international ""La communication numérique au cœur des sociétés : dispositifs, logiques de développement et pratiques"". ",api,True,findable,0,0,0,0,0,2024-03-06T22:51:37.000Z,2024-03-06T22:51:38.000Z,fmsh.prod,fmsh,"Sciences de l'information et de la communication,Communication","[{'subject': ""Sciences de l'information et de la communication""}, {'subject': 'Communication'}]",,['video/mp4'],,,['IsPartOf'],
10.6084/m9.figshare.c.5657338,Open-label randomized controlled trial of ultra-low tidal ventilation without extracorporeal circulation in patients with COVID-19 pneumonia and moderate to severe ARDS: study protocol for the VT4COVID trial,figshare,2021,,Collection,Creative Commons Attribution 4.0 International,"Abstract Background Acute respiratory distress syndrome (ARDS) is a severe complication of COVID-19 pneumonia, with a mortality rate amounting to 34–50% in moderate and severe ARDS, and is associated with prolonged duration of invasive mechanical ventilation. Such as in non-COVID ARDS, harmful mechanical ventilation settings might be associated with worse outcomes. Reducing the tidal volume down to 4 mL kg−1 of predicted body weight (PBW) to provide ultra-low tidal volume ventilation (ULTV) is an appealing technique to minimize ventilator-inducted lung injury. Furthermore, in the context of a worldwide pandemic, it does not require any additional material and consumables and may be applied in low- to middle-income countries. We hypothesized that ULTV without extracorporeal circulation is a credible option to reduce COVID-19-related ARDS mortality and duration of mechanical ventilation. Methods The VT4COVID study is a randomized, multi-centric prospective open-labeled, controlled superiority trial. Adult patients admitted in the intensive care unit with COVID-19-related mild to severe ARDS defined by a PaO2/FiO2 ratio ≤ 150 mmHg under invasive mechanical ventilation for less than 48 h, and consent to participate to the study will be eligible. Patients will be randomized into two balanced parallels groups, at a 1:1 ratio. The control group will be ventilated with protective ventilation settings (tidal volume 6 mL kg−1 PBW), and the intervention group will be ventilated with ULTV (tidal volume 4 mL kg−1 PBW). The primary outcome is a composite score based on 90-day all-cause mortality as a prioritized criterion and the number of ventilator-free days at day 60 after inclusion. The randomization list will be stratified by site of recruitment and generated using random blocks of sizes 4 and 6. Data will be analyzed using intention-to-treat principles. Discussion The purpose of this manuscript is to provide primary publication of study protocol to prevent selective reporting of outcomes, data-driven analysis, and to increase transparency. Enrollment of patients in the study is ongoing. Trial registration ClinicalTrials.gov NCT04349618 . Registered on April 16, 2020",mds,True,findable,0,0,0,0,0,2021-10-12T03:37:53.000Z,2021-10-12T03:37:55.000Z,figshare.ars,otjm,"Medicine,Cell Biology,Physiology,FOS: Biological sciences,Biotechnology,Cancer,Mental Health,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': 'Biotechnology'}, {'subject': 'Cancer'}, {'subject': 'Mental Health'}, {'subject': 'Computational Biology'}]",,,,,,
10.5061/dryad.cv45n3b,"Data from: Circadian periodicity in space use by ungulates of temperate regions: how much, when, and why?",Dryad,2019,en,Dataset,Creative Commons Zero v1.0 Universal,"1. When they visit and revisit specific areas, animals may reveal what
they need from their home range and how they acquire information. The
temporal dimension of such movement recursions, i.e., periodicity, is
however rarely studied, yet potentially bears a species, population, or
individual-specific signature. 2. A recent method allows estimating the
contribution of periodic patterns to the variance in a movement path. We
applied it to 709 individuals from 5 ungulate species, looking for species
signatures in the form of seasonal variation in the intensity of circadian
patterns. 3. Circadian patterns were commonplace in the movement tracks,
but the amount of variance they explained was highly variable among
individuals. It increased in intensity during spring and summer, when key
resources were spatially segregated, and decreased during winter, when
food availability was more uniformly low. Other periodicity-inducing
mechanisms supported by our comparison of species- and sex-specific
patterns involve young anti-predator behavior, territoriality, and
behavioral thermoregulation. 4. Model-based continuous-time movement
metrics represent a new avenue for researchers interested in finding
individual-, population-, or species-specific signatures in heterogeneous
movement databases featuring various study designs and sampling
resolutions. However, we observed large amounts of individual variation,
so comparative analyses should ideally use both GPS and animal-borne
loggers to augment the discriminatory power; and be based on large
samples. We briefly outline potential uses of the intensity of circadian
patterns as a metric for the study of animal personality and community
ecology.",mds,True,findable,204,16,1,1,0,2018-05-11T13:19:14.000Z,2018-05-11T13:19:15.000Z,dryad.dryad,dryad,"Capra ibex,Environmental cycles,ovis musimon,Cervus elaphus,spectral analysis,rupicapra rupicapra,Capreolus capreolus","[{'subject': 'Capra ibex'}, {'subject': 'Environmental cycles'}, {'subject': 'ovis musimon'}, {'subject': 'Cervus elaphus'}, {'subject': 'spectral analysis'}, {'subject': 'rupicapra rupicapra'}, {'subject': 'Capreolus capreolus'}]",['415233 bytes'],,,,['IsCitedBy'],
10.5281/zenodo.4601171,RUSTInA: Automatically checking and Patching Inline Assembly Interface Compliance (Artifact Evaluation),Zenodo,2021,en,Software,"Creative Commons Attribution 4.0 International,Open Access","The main goal of the artifact is to support the experimental claims of the paper #992 “Interface Compliance of Inline Assembly: Automatically Check, Patch and Refine” by making both the prototype and data available to the community. The expected result is the same output as the figures given in Table I and Table IV (appendix C) of the paper. In addition, we hope the released snapshot of our prototype is simple, documented and robust enough to have some uses for people dealing with inline assembly. The artifact is made publicly available on Github at: https://github.com/binsec/icse2021-artifact992/, and more information on RUSTInA can be found at https://binsec.github.io/new/publication/1970/01/01/nutshell-icse-21.html.",mds,True,findable,0,0,0,0,0,2021-03-12T13:58:36.000Z,2021-03-12T13:58:37.000Z,cern.zenodo,cern,"low-level programming,inline assembly,compilation issues,program analysis","[{'subject': 'low-level programming'}, {'subject': 'inline assembly'}, {'subject': 'compilation issues'}, {'subject': 'program analysis'}]",,,,,['HasVersion'],"[['IsVersionOf', '10.5281/zenodo.4601171']]"
10.6084/m9.figshare.16851102,Additional file 1 of The mitochondrially-localized nucleoside diphosphate kinase D (NME4) is a novel metastasis suppressor,figshare,2021,,Text,Creative Commons Attribution 4.0 International,"Additional file 1: Fig. S1. NDPK protein expression, kinase activity, and subcellular localization in HeLa clones. HeLa cells were stably transfected with empty vector pcDNA4TO (CTR) or constructs for expression of NDPK-D WT (WT), CL-binding deficient R90D (BD) or kinase dead H151N (KD). A) Immunoblot detection of NDPK-D (NME4) in extracts of the transfected HeLa cells with α-tubulin as loading control. B) NDP kinase activity in purified HeLa mitochondria. Values are means ± SEM (n=3). C) HeLa clones stably transfected with empty vector (CTR), or expressing NDPK-D WT, BD or KD mutants, showing identical labeling of mitochondrion-selective dye MitoTracker Red CMXRos (red) and immunolabeled NDPK-D (green). Mitochondrial network details are indicated by faint line boxes magnified in bold line boxes. Scale bar, 10 μm. D) Immunoblot detection of NDPK-A (NME1) and NDPK-B (NME2) in extracts of the transfected HeLa cells with α-tubulin as loading control.",mds,True,findable,0,0,93,1,0,2021-10-22T04:05:10.000Z,2021-10-22T04:05:13.000Z,figshare.ars,otjm,"Biophysics,Biochemistry,Medicine,Cell Biology,Genetics,FOS: Biological sciences,Molecular Biology,Physiology,Immunology,FOS: Clinical medicine,Developmental Biology,Cancer,Hematology,Infectious Diseases,FOS: Health sciences,Computational Biology","[{'subject': 'Biophysics'}, {'subject': 'Biochemistry'}, {'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': 'Physiology'}, {'subject': 'Immunology'}, {'subject': 'FOS: Clinical medicine', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': 'Developmental Biology'}, {'subject': 'Cancer'}, {'subject': 'Hematology'}, {'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'}]",['3318853 Bytes'],,,,"['IsIdenticalTo', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'IsSupplementTo']","[['IsIdenticalTo', '10.6084/m9.figshare.16851102']]"
10.17178/amma-catch.ce.gwat_odc,"Groundwater dataset (water table level), over the Donga watershed (600 km2), Benin","IRD, CNRS-INSU, OSUG, OMP, OREME",2003,en,Dataset,"Creative Commons Attribution 4.0 International,Data access and use are ruled by the AMMA-CATCH data policy.,For any publication using AMMA-CATCH data, authors are asked to:
Mandatory: cite the reference article and the DOI of the observatory
(1) Galle et al. (2018). AMMA-CATCH a Critical Zone Observatory in West Africa Monitoring a Region in Transition. Vadose Zone Journal, 17 (1), 18006.
(2) AMMA-CATCH (1990). AMMA-CATCH : a hydrological, meteorological and ecological observatory on West Africa. IRD, CNRS-INSU, OSUG, OMP, OREME. doi:10.17178/AMMA-CATCH.all
Optional: cite the DOI of each dataset used.
Co-authorship: depending on the contribution of the data to the scientific results obtained, the authors should either propose co-authorship to the data providers or at least acknowledge their contribution.","Documentation of the processes of groundwater recharge-discharge. Documentation of the groundwater-river connections. Contribution to the water budget at the hillslope scale in relation with soil water, runoff measurements. The identified processes will be used to improve hydrological modelling at the super-site scale (Donga).",mds,True,findable,0,0,1,0,0,2018-03-16T15:36:57.000Z,2018-03-16T15:36:57.000Z,inist.osug,jbru,"Aquifer, recharge, groundwater,Sudanian climate,Water Table","[{'subject': 'Aquifer, recharge, groundwater', 'subjectScheme': 'main'}, {'subject': 'Sudanian climate', 'subjectScheme': 'main'}, {'subject': 'Water Table', 'subjectScheme': 'var'}]",,"['CSV', 'NETCDF', 'O&M 1.0']",,,"['Cites', 'IsPartOf', 'IsPartOf']",
10.5281/zenodo.6035533,"Consilience across multiple, independent genomic data sets reveals species in a complex with limited phenotypic variation",Zenodo,2023,,Software,"MIT License,Open Access","Species delimitation in the genomic era has focused predominantly on the application of multiple analytical methodologies to a single massive parallel sequencing (MPS) data set, rather than leveraging the unique but complementary insights provided by different classes of MPS data. In this study we demonstrate how the use of two independent MPS data sets, a sequence capture data set and a single nucleotide polymorphism (SNP) data set generated via genotyping-by-sequencing, enables the resolution of species in three complexes belonging to the grass genus <em>Ehrharta, </em>whose strong population structure and subtle morphological variation limit the effectiveness of traditional species delimitation approaches. Sequence capture data are used to construct a comprehensive phylogenetic tree of <em>Ehrharta </em>and to resolve population relationships within the focal clades, while SNP data are used to detect patterns of gene pool sharing across populations, using a novel approach that visualises multiple values of K. Given that the two genomic data sets are fully independent, the strong congruence in the clusters they resolve provides powerful ratification of species boundaries in all three complexes studied. Our approach is also able to resolve a number of single-population species and a probable hybrid species, both which would be difficult to detect and characterize using a single MPS data set. Overall, the data reveal the existence of 11 and five species in the <em>E. setacea</em> and <em>E. rehmannii </em>complexes, with the <em>E. ramosa</em> complex requiring further sampling before species limits are finalized. Despite phenotypic differentiation being generally subtle, true crypsis is limited to just a few species pairs and triplets. We conclude that, in the absence of strong morphological differentiation, the use of multiple, independent genomic data sets is necessary in order to provide the cross-data set corroboration that is foundational to an integrative taxonomic approach.",mds,True,findable,0,0,0,0,0,2023-02-14T19:26:17.000Z,2023-02-14T19:26:17.000Z,cern.zenodo,cern,,,,,,,"['IsSourceOf', 'HasVersion', 'IsPartOf']","[['IsVersionOf', '10.5281/zenodo.6035533']]"
10.17178/emaa_dcn_hyperfine_0b4f7ab6,Hyperfine excitation of DCN by electron and para-H2 collisions,"UGA, CNRS, CNRS-INSU, OSUG",2021,en,Dataset,"Please acknowledge the use of EMAA Database by citing the original articles in which the data were published (BibTeX format available), and adding the following sentence in your publication:
This research has made use of spectroscopic and collisional data from the EMAA database (https://emaa.osug.fr). EMAA is supported by the Observatoire des Sciences de l'Univers de Grenoble (OSUG),Creative Commons Attribution 4.0 International,Data access and use are ruled by the EMAA data policy.",19 hyperfine energy levels / 33 radiative transitions / 171 collisional transitions for para-H2 (6 temperatures in the range 5-30K) / 165 collisional transitions for electron (10 temperatures in the range 10-1000K),mds,True,findable,0,0,0,0,0,2022-02-07T11:24:23.000Z,2022-02-07T11:24:24.000Z,inist.osug,jbru,"target DCN,excitationType Hyperfine,collisional excitation,collider.0 para-H2,collider.1 electron,astrophysics,interstellar medium,comets,circumstellar medium,gas,microwave spectroscopy,infrared spectroscopy,rotational excitation,rovibrational excitation,vibrational excitation,electronic excitation,collisional rate coefficients,fine structure,hyperfine structure","[{'subject': 'target DCN', 'subjectScheme': 'main'}, {'subject': 'excitationType Hyperfine', 'subjectScheme': 'main'}, {'subject': 'collisional excitation', 'subjectScheme': 'main'}, {'subject': 'collider.0 para-H2', 'subjectScheme': 'var'}, {'subject': 'collider.1 electron', 'subjectScheme': 'var'}, {'subject': 'astrophysics', 'subjectScheme': 'var'}, {'subject': 'interstellar medium', 'subjectScheme': 'var'}, {'subject': 'comets', 'subjectScheme': 'var'}, {'subject': 'circumstellar medium', 'subjectScheme': 'var'}, {'subject': 'gas', 'subjectScheme': 'var'}, {'subject': 'microwave spectroscopy', 'subjectScheme': 'var'}, {'subject': 'infrared spectroscopy', 'subjectScheme': 'var'}, {'subject': 'rotational excitation', 'subjectScheme': 'var'}, {'subject': 'rovibrational excitation', 'subjectScheme': 'var'}, {'subject': 'vibrational excitation', 'subjectScheme': 'var'}, {'subject': 'electronic excitation', 'subjectScheme': 'var'}, {'subject': 'collisional rate coefficients', 'subjectScheme': 'var'}, {'subject': 'fine structure', 'subjectScheme': 'var'}, {'subject': 'hyperfine structure', 'subjectScheme': 'var'}]",,['Radex'],,,"['Cites', 'IsPartOf', 'References', 'References', 'References']",
10.5281/zenodo.10061546,FIG. 4 in Passiflora tinifolia Juss. (Passiflora subgenus Passiflora): resurrection and synonymies,Zenodo,2023,,Image,Creative Commons Attribution 4.0 International,"FIG. 4. — Passiflora tinifolia Juss., French Guiana (photos: Maxime Rome): A, young leaf with glands at the apex of the petiole and linear stipules; B, mature leaf with peduncles gathered in a pseudoraceme; C, flower bud with bracts; D, flower; E, longitudinal section of flower; F, immature and mature fruit.",api,True,findable,0,0,0,3,0,2023-11-01T12:50:46.000Z,2023-11-01T12:50:46.000Z,cern.zenodo,cern,"Biodiversity,Taxonomy,Plantae,Tracheophyta,Magnoliopsida,Malpighiales,Passifloraceae,Passiflora","[{'subject': 'Biodiversity'}, {'subject': 'Taxonomy'}, {'subject': 'Plantae'}, {'subject': 'Tracheophyta'}, {'subject': 'Magnoliopsida'}, {'subject': 'Malpighiales'}, {'subject': 'Passifloraceae'}, {'subject': 'Passiflora'}]",,,,,"['IsPartOf', 'IsPartOf', 'IsPartOf', 'IsCitedBy', 'IsCitedBy', 'HasVersion']","[['IsVersionOf', '10.5281/zenodo.10061546']]"
10.5281/zenodo.3947756,Optimal Exclusive Perpetual Grid Exploration by Luminous Myopic Opaque Robots: The Animations,Zenodo,2020,,Audiovisual,"CeCILL-B Free Software License Agreement,Open Access","Animations of three optimal perpetual grid exploration algorithms. The published HTML pages allow the viewer to see the first 300 rounds of the algorithms, for different initial configurations. To view the animation without downloading them, they are also accessible at the following urls: https://bramas.fr/static/ICDCN2021/2-robots-3-colors-range-1.html https://bramas.fr/static/ICDCN2021/2-robots-2-colors-range-2.html https://bramas.fr/static/ICDCN2021/3-robots-1-color-range-2.html https://bramas.fr/static/TCS2021/4-robots-1-color-terminating.html https://bramas.fr/static/TCS2021/2-robot-7-colors-terminating.html",mds,True,findable,0,0,0,0,0,2021-07-30T14:34:04.000Z,2021-07-30T14:34:04.000Z,cern.zenodo,cern,"Mobile robots, distributed algorithms","[{'subject': 'Mobile robots, distributed algorithms'}]",,,,,"['HasVersion', 'HasVersion', 'HasVersion', 'HasVersion']","[['IsVersionOf', '10.5281/zenodo.3947756']]"
10.60527/nnhk-n811,Les dispositifs et l'évolution des pratiques,"Univ. Grenoble Alpes, GRESEC",2015,,Other,,,api,True,findable,0,0,0,0,0,2024-03-06T22:51:13.000Z,2024-03-06T22:51:13.000Z,fmsh.prod,fmsh,,,,,,,"['IsPartOf', 'IsPartOf', 'IsPartOf', 'IsPartOf', 'IsPartOf', 'IsPartOf', 'IsPartOf']",
10.5281/zenodo.11123210,A functional characterization of bioengineered plant communities along riverbanks,Zenodo,2024,,Dataset,Creative Commons Attribution 4.0 International,"Frequency of occurrence and information for 10 traits and 3 attributes of 356 plant taxa identified in 84 riverbank sites stabilized with soil bioengineering and in 40 reference (natural) sites in the eastern Canadian province of Quebec, Canada. Traits and attributes were obtained from the literature (different sources). The data release includes three files containing three datasets of site x species, species x traits, and trait sources. Each file contains a metadata tab with a detailed description of columns.",api,True,findable,0,0,0,0,1,2024-05-16T18:05:10.000Z,2024-05-16T18:05:10.000Z,cern.zenodo,cern,,,,,,,"['IsPublishedIn', 'HasVersion', 'IsPartOf']",
10.5281/zenodo.6319385,Structural Basis for the Inhibition of IAPP Fibril Formation by the Co-Chaperonin Prefoldin - Experimental Data,Zenodo,2022,,Dataset,"Creative Commons Attribution 4.0 International,Open Access","Experimental data (EM, AFM, BLI, ThT and Cell viability assays, as well as docking models) used for the study : <strong>Structural Basis for the Inhibition of IAPP Fibril Formation by the </strong><strong>Co-Chaperonin Prefoldin</strong> by Ricarda Törner, Tatsiana Kupreichyk, Lothar Gremer, Elisa Colas Debled, Daphna Fenel, Sarah Schemmert, Pierre Gans<sub>, </sub>Dieter Willbold, Guy Schoehn, Wolfgang Hoyer, Jerome Boisbouvier",mds,True,findable,0,0,0,0,0,2022-03-01T08:03:24.000Z,2022-03-01T08:03:25.000Z,cern.zenodo,cern,,,,,,,['HasVersion'],"[['IsVersionOf', '10.5281/zenodo.6319385']]"
10.5281/zenodo.4417416,"Spatial slip rate distribution along the SE Xianshuihe fault, eastern Tibet, and earthquake hazard assessment",Zenodo,2021,en,Dataset,"Creative Commons Attribution 4.0 International,Open Access",<strong><em>Table 2: </em></strong><em><sup>10</sup></em><em>Be surface-exposure ages of Zheduotang (ZDT) and Moxi (MX) sites of the SE Xianshuihe fault.</em>,mds,True,findable,0,0,0,0,0,2021-07-16T02:27:16.000Z,2021-07-16T02:27:17.000Z,cern.zenodo,cern,"Xianshuihe fault,eastern Tibet,cosmogenic dating,tectonic-geomorphology,late Quaternary slip rates,active pull apart basin,earthquake hazard","[{'subject': 'Xianshuihe fault'}, {'subject': 'eastern Tibet'}, {'subject': 'cosmogenic dating'}, {'subject': 'tectonic-geomorphology'}, {'subject': 'late Quaternary slip rates'}, {'subject': 'active pull apart basin'}, {'subject': 'earthquake hazard'}]",,,,,"['IsNewVersionOf', 'HasVersion', 'HasVersion']","[['IsVersionOf', '10.5281/zenodo.4417416']]"
10.5061/dryad.wdbrv15wb,"Ecological niche modelling to project past, current and future distributional shift of black ebony tree (Diospyros melanoxylon Roxb.) in India",Dryad,2024,en,Dataset,Creative Commons Zero v1.0 Universal,"The present study utilized an ensemble modelling approach to predict the
distribution of D. melanoxylon under present, past (Last Glacial Maximum,
~22,000 cal yr BP, Middle Holocene ~6000 cal yr BP) and future climate
change scenarios (RCP 2.6 and 8.5 for 2050s and 2070s). The annual mean
temperature, mean temperature of the wettest quarter and annual
precipitations were the most critical parameters that chiefly influence
the distribution of D. melanoxylon. The ensemble model rendered high
accuracy with AUC=0.93, TSS=0.74, and Kappa=0.71. Past projections of D.
melanoxylon indicated a widespread distribution during the Last Glacial
Maximum and Middle Holocene suggesting its adaptability to semi-dry as
well as warm and humid climates, respectively. The presence of fossil
pollen evidence of D. melanoxylon in the suitable habitats derived through
past projections in this study complements the model results and marks
occurrences of the species during the Last Glacial Maximum and Middle
Holocene. By 2050s and 2070s (RCP 8.5), there would be a decline in the
distribution by only 0.4% (13622 km2) and 0.2% (6842 km2) of the extremely
habitat suitable, respectively. The main factor leading to reduced habitat
suitability is the anticipated rise in temperature and variations in
seasonal precipitation patterns. Our findings, help in identifying the
parts of the country which would be severely affected by future climate
change scenarios and plan conservation strategies for this commercially
important species to facilitate its growth in suitable habitats which are
likely to sustain under future climatic conditions.",mds,True,findable,0,0,0,0,0,2024-02-27T18:03:59.000Z,2024-02-27T18:04:00.000Z,dryad.dryad,dryad,"FOS: Natural sciences,FOS: Natural sciences,Species distribution model,Climate change,habitat suitability,Diospyros melanoxylon,Conservation","[{'subject': 'FOS: Natural sciences', 'subjectScheme': 'fos'}, {'subject': 'FOS: Natural sciences', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': 'Species distribution model'}, {'subject': 'Climate change', 'schemeUri': 'https://github.com/PLOS/plos-thesaurus', 'subjectScheme': 'PLOS Subject Area Thesaurus'}, {'subject': 'habitat suitability'}, {'subject': 'Diospyros melanoxylon'}, {'subject': 'Conservation'}]",['587063304 bytes'],,,,,
10.6084/m9.figshare.13646872,Additional file 1 of Performance of the ROX index to predict intubation in immunocompromised patients receiving high-flow nasal cannula for acute respiratory failure,figshare,2021,,Text,Creative Commons Attribution 4.0 International,Additional file 1: Figure S1. ROC curve for ROX index 6 hours after HFNC onset. Figure S2. Probability of intubation according to the multivariable model including ROX index. Figure S3. ROC curve of adjusted ROX index 6 hours after HFNC onset. Figure S4. Comparison between ROC curves of adjusted ROX index and modified model without ROX index. Figure S5. Probability of intubation according to ROX index quartile.,mds,True,findable,0,0,17,1,0,2021-01-27T04:12:36.000Z,2021-01-27T04:12:40.000Z,figshare.ars,otjm,"Medicine,Sociology,FOS: Sociology,Immunology,FOS: Clinical medicine,Biological Sciences not elsewhere classified,Science Policy,Hematology,Virology","[{'subject': 'Medicine'}, {'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': 'Biological Sciences not elsewhere classified'}, {'subject': 'Science Policy'}, {'subject': 'Hematology'}, {'subject': 'Virology'}]",['6144606 Bytes'],,,,"['References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'IsSupplementTo']",
10.5281/zenodo.3901436,GazeEEGSynchro,Zenodo,2021,,Software,"Creative Commons Attribution 4.0 International,Open Access",The GazeEegSynchro software runs under DOS. It allows to synchronize data coming from Eyelink ASC data files and Brainamp EEG+VHDR+VMRK data files. The synchronization process is based on piecewise linear alignments of shared triggers in both acquisition devices. <strong>A gitlab project is also available.</strong>,mds,True,findable,0,0,0,0,0,2021-11-22T10:33:25.000Z,2021-11-22T10:33:26.000Z,cern.zenodo,cern,"EEG,co-registration,synchronization,clock-drift,drift correction,eye movements","[{'subject': 'EEG'}, {'subject': 'co-registration'}, {'subject': 'synchronization'}, {'subject': 'clock-drift'}, {'subject': 'drift correction'}, {'subject': 'eye movements'}]",,,,,"['HasVersion', 'HasVersion', 'HasVersion', 'HasVersion']","[['IsVersionOf', '10.5281/zenodo.3901436']]"
10.5281/zenodo.11068835,The Role of Thermomechanical Stresses in the Explosive Spalling of Refractory Castables: A Numerical Study,Zenodo,2024,en,Text,Creative Commons Attribution 4.0 International,"The drying of hydraulic bonded refractory castables is the longest step of its installation process hindering higher efficiency and leading to larger CO2 emissions. This overconservative approach is a result of several cases of explosive spalling, which can be observed when fast heating rates are applied. Currently, it is assumed that the mechanisms behind this phenomenon are related to the combined stresses resulting from the water vapor pressure within the castable's pores and from the differential thermal expansion of the lining. In industrial practice, most of the strategies employed to mitigate the risk of explosions focus on the former mechanism, such as the use of polymeric fibers to increase the material's permeability. The current study aims to analyze the role of thermomechanical stresses on explosive spalling through numerical simulations. The main objective is to provide additional strategies to minimize the likelihood of facing such catastrophic events through the control of the thermal stresses inside the refractory lining. It was found that the heterogeneous heating in the vertical direction led to significant stress levels that contributed to the appearance of explosive spalling. Thus, the use of more homogeneous heating could enable faster and safer water withdrawal.",api,True,findable,0,0,0,0,0,2024-04-25T19:34:26.000Z,2024-04-25T19:34:26.000Z,cern.zenodo,cern,,,,,,,['HasVersion'],"[['IsVersionOf', '10.5281/zenodo.11068835']]"
10.17178/amma-catch.cl.rain_g,"Precipitation dataset (5 minutes rainfall), over the Hombori site (2500 km2 ), Mali","IRD, CNRS-INSU, OSUG, OMP, OREME",2005,en,Dataset,"Creative Commons Attribution 4.0 International,Data access and use are ruled by the AMMA-CATCH data policy.,For any publication using AMMA-CATCH data, authors are asked to:
Mandatory: cite the reference article and the DOI of the observatory
(1) Galle et al. (2018). AMMA-CATCH a Critical Zone Observatory in West Africa Monitoring a Region in Transition. Vadose Zone Journal, 17 (1), 18006.
(2) AMMA-CATCH (1990). AMMA-CATCH : a hydrological, meteorological and ecological observatory on West Africa. IRD, CNRS-INSU, OSUG, OMP, OREME. doi:10.17178/AMMA-CATCH.all
Optional: cite the DOI of each dataset used.
Co-authorship: depending on the contribution of the data to the scientific results obtained, the authors should either propose co-authorship to the data providers or at least acknowledge their contribution.","Documentation of rainfall in sahelian and saharo-sahelian zones. The aim is to characterize the spatial and temporal variability of rainfall within a densified zone of approximately 0°7 by 0°7 degrees within the Gourma meso-scale site. Data will be used in modelling and assimilation activities, as well as for validation of satellite products.",mds,True,findable,0,0,1,0,0,2018-03-16T15:37:13.000Z,2018-03-16T15:37:13.000Z,inist.osug,jbru,"Rainfall, precipitation, tropical convection,Sahelian/Saharan climate,Precipitation Amount (previous hour),Precipitation Amount (previous 24 hours),Precipitation Amount (previous 5 minutes)","[{'subject': 'Rainfall, precipitation, tropical convection', 'subjectScheme': 'main'}, {'subject': 'Sahelian/Saharan climate', 'subjectScheme': 'main'}, {'subject': 'Precipitation Amount (previous hour)', 'subjectScheme': 'var'}, {'subject': 'Precipitation Amount (previous 24 hours)', 'subjectScheme': 'var'}, {'subject': 'Precipitation Amount (previous 5 minutes)', 'subjectScheme': 'var'}]",,"['CSV', 'NETCDF', 'O&M 1.0']",,,"['Cites', 'IsPartOf', 'IsPartOf']",
10.5061/dryad.8cz8w9gqs,Can functional genomic diversity provide novel insights into mechanisms of community assembly? A pilot-study from an invaded alpine streambed,Dryad,2021,en,Dataset,Creative Commons Zero v1.0 Universal,"An important focus of community ecology, including invasion biology, is to
investigate functional trait diversity patterns to disentangle the effects
of environmental and biotic interactions. However, a notable limitation is
that studies usually rely on a small and easy to measure set of functional
traits, which might not immediately reflect ongoing ecological responses
to changing abiotic or biotic conditions, including those that occur at a
molecular or physiological level. We explored the potential of using the
diversity of expressed genes—functional genomic diversity (FGD)—to
understand ecological dynamics of a recent and ongoing alpine invasion. We
quantified FGD based on transcriptome data measured for 26 plant species
occurring along adjacent invaded and pristine streambeds. We used an
RNA-seq approach to summarize the overall number of expressed transcripts
and their annotations to functional categories, and contrasted this with
functional trait diversity (FTD) measured from a suite of characters that
have been traditionally considered in plant ecology. We found greater FGD
and FTD in the invaded community, independent of differences in species
richness. However, the magnitude of functional dispersion was greater from
the perspective of FGD than from FTD. Comparing FGD between congeneric
alien-native species pairs, we did not find many significant differences
in the proportion of genes whose annotations matched functional
categories. Still, native species with a greater relative abundance in the
invaded community compared with the pristine tended to express a greater
fraction of genes at significant levels in the invaded community,
suggesting that changes in FGD may relate to shifts in community
composition. Comparisons of diversity patterns from the community- to the
species-level offer complementary insights into processes and mechanisms
driving invasion dynamics. FGD has the potential to illuminate cryptic
changes in ecological diversity, and we foresee promising avenues for
future extensions across taxonomic levels and macro-ecosystems. ",mds,True,findable,127,3,0,0,0,2021-07-22T01:16:51.000Z,2021-07-22T01:16:53.000Z,dryad.dryad,dryad,,,['1658541920 bytes'],,,,,
10.5281/zenodo.5905876,IC profile analysis V.1.0,Zenodo,2022,,Software,Open Access,"This R script performs a longitudinal analysis on the output of IC (Cavalli et al.,(2013), and its composing parameters according to Torresani et al., (2021). The analysis is performed on exported CSV table containing the IC and the selected parameters extracted along the channel profile. This tool aims to graphically represent the behaviour of the variables at different locations of the analysed channel.",mds,True,findable,0,0,1,0,0,2022-01-26T11:27:45.000Z,2022-01-26T11:27:46.000Z,cern.zenodo,cern,,,,,,,"['IsSupplementTo', 'HasVersion']","[['IsVersionOf', '10.5281/zenodo.5905876']]"
10.17178/emaa_ortho-nh3_hyperfine_22b1dfb7,Hyperfine excitation of ortho-NH3 by para-H2 collisions,"UGA, CNRS, CNRS-INSU, OSUG",2023,en,Dataset,"Please acknowledge the use of EMAA Database by citing the original articles in which the data were published (BibTeX format available), and adding the following sentence in your publication:
This research has made use of spectroscopic and collisional data from the EMAA database (https://emaa.osug.fr). EMAA is supported by the Observatoire des Sciences de l'Univers de Grenoble (OSUG),Creative Commons Attribution 4.0 International,Data access and use are ruled by the EMAA data policy.",25 hyperfine energy levels / 47 radiative transitions / 300 collisional transitions for para-H2 (11 temperatures in the range 5-100K),mds,True,findable,0,0,0,0,0,2023-12-07T15:51:55.000Z,2023-12-07T15:51:56.000Z,inist.osug,jbru,"target ortho-NH3,excitationType Hyperfine,collisional excitation,collider.0 para-H2,astrophysics,interstellar medium,comets,circumstellar medium,gas,microwave spectroscopy,infrared spectroscopy,rotational excitation,rovibrational excitation,vibrational excitation,electronic excitation,collisional rate coefficients,fine structure,hyperfine structure","[{'subject': 'target ortho-NH3', 'subjectScheme': 'main'}, {'subject': 'excitationType Hyperfine', 'subjectScheme': 'main'}, {'subject': 'collisional excitation', 'subjectScheme': 'main'}, {'subject': 'collider.0 para-H2', 'subjectScheme': 'var'}, {'subject': 'astrophysics', 'subjectScheme': 'var'}, {'subject': 'interstellar medium', 'subjectScheme': 'var'}, {'subject': 'comets', 'subjectScheme': 'var'}, {'subject': 'circumstellar medium', 'subjectScheme': 'var'}, {'subject': 'gas', 'subjectScheme': 'var'}, {'subject': 'microwave spectroscopy', 'subjectScheme': 'var'}, {'subject': 'infrared spectroscopy', 'subjectScheme': 'var'}, {'subject': 'rotational excitation', 'subjectScheme': 'var'}, {'subject': 'rovibrational excitation', 'subjectScheme': 'var'}, {'subject': 'vibrational excitation', 'subjectScheme': 'var'}, {'subject': 'electronic excitation', 'subjectScheme': 'var'}, {'subject': 'collisional rate coefficients', 'subjectScheme': 'var'}, {'subject': 'fine structure', 'subjectScheme': 'var'}, {'subject': 'hyperfine structure', 'subjectScheme': 'var'}]",,['Radex'],,,"['Cites', 'IsPartOf', 'References', 'References']",
10.6084/m9.figshare.17006979,Additional file 1 of Targeted high mean arterial pressure aggravates cerebral hemodynamics after extracorporeal resuscitation in swine,figshare,2021,,Text,Creative Commons Attribution 4.0 International,"Additional file 1. Supplemental Table I: P values of the contingency table of the two-way analysis of variance (ANOVA) for repeated measures with group, time effect and group x time interaction effects for the different investigated parameters after cardiac arrest.",mds,True,findable,0,0,17,1,0,2021-11-14T04:19:24.000Z,2021-11-14T04:19:25.000Z,figshare.ars,otjm,"Medicine,Neuroscience,Biological Sciences not elsewhere classified","[{'subject': 'Medicine'}, {'subject': 'Neuroscience'}, {'subject': 'Biological Sciences not elsewhere classified'}]",['30160 Bytes'],,,,"['IsIdenticalTo', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'IsSupplementTo']","[['IsIdenticalTo', '10.6084/m9.figshare.17006979']]"
10.57745/nohrhj,Spatial variability of rainfall driven erosion at the catchment scale: the June 23rd 2010 rainfall event on the Galabre catchment,Recherche Data Gouv,2023,,Dataset,,"This dataset is related to the Galabre basin, a 20 km² headwater catchment located in the French Alps that is part of the Draix-Bléone Observatory. Liquid and solid discharges are continuously monitored at the catchment outlet (Legout et al. 2021). Soil erosion was modelled for a rainfall event recorded on June 23rd 2010, prescribing the effective rainfall intensity in two different ways: 1) as spatially distributed rainfall fields defined from raster files with spatial and temporal resolutions of 1 km and 15 minutes respectively, and 2) as spatially uniform rainfall fields defined as the spatial average of the rainfall fields over the entire catchment, with a time resolution of 15 minutes. Both rainfall products are equivalent in terms of the spatial average of rainfall intensity at each time step. The only difference between both simulations was the spatial variability of rainfall. The dataset contains two Iber+ models with either options of modelling rainfall, including the rainfall data as .asc rasters, as well as a spreadsheets with the output results of the simulation. The Iber+ model should be run with the executables provided by CEA & GARCIA-FEAL 2023, ""Iber+ executables (V3.2b)"", https://doi.org/10.57745/UFEK4L.",mds,True,findable,24,0,0,0,0,2023-04-04T15:34:19.000Z,2023-04-04T15:57:23.000Z,rdg.prod,rdg,,,,,,,"['HasPart', 'HasPart']",
10.17178/emaa_para-nd3_rotation_da7fd1bd,Rotation excitation of para-ND3 by para-H2 collisions,"UGA, CNRS, CNRS-INSU, OSUG",2021,en,Dataset,"Please acknowledge the use of EMAA Database by citing the original articles in which the data were published (BibTeX format available), and adding the following sentence in your publication:
This research has made use of spectroscopic and collisional data from the EMAA database (https://emaa.osug.fr). EMAA is supported by the Observatoire des Sciences de l'Univers de Grenoble (OSUG),Creative Commons Attribution 4.0 International,Data access and use are ruled by the EMAA data policy.",9 rotation energy levels / 8 radiative transitions / 36 collisional transitions for para-H2 (8 temperatures in the range 5-40K),mds,True,findable,0,0,0,0,0,2021-11-17T14:02:08.000Z,2021-11-17T14:02:09.000Z,inist.osug,jbru,"target para-ND3,excitationType Rotation,collisional excitation,collider.0 para-H2,astrophysics,interstellar medium,comets,circumstellar medium,gas,microwave spectroscopy,infrared spectroscopy,rotational excitation,rovibrational excitation,vibrational excitation,electronic excitation,collisional rate coefficients,fine structure,hyperfine structure","[{'subject': 'target para-ND3', 'subjectScheme': 'main'}, {'subject': 'excitationType Rotation', 'subjectScheme': 'main'}, {'subject': 'collisional excitation', 'subjectScheme': 'main'}, {'subject': 'collider.0 para-H2', 'subjectScheme': 'var'}, {'subject': 'astrophysics', 'subjectScheme': 'var'}, {'subject': 'interstellar medium', 'subjectScheme': 'var'}, {'subject': 'comets', 'subjectScheme': 'var'}, {'subject': 'circumstellar medium', 'subjectScheme': 'var'}, {'subject': 'gas', 'subjectScheme': 'var'}, {'subject': 'microwave spectroscopy', 'subjectScheme': 'var'}, {'subject': 'infrared spectroscopy', 'subjectScheme': 'var'}, {'subject': 'rotational excitation', 'subjectScheme': 'var'}, {'subject': 'rovibrational excitation', 'subjectScheme': 'var'}, {'subject': 'vibrational excitation', 'subjectScheme': 'var'}, {'subject': 'electronic excitation', 'subjectScheme': 'var'}, {'subject': 'collisional rate coefficients', 'subjectScheme': 'var'}, {'subject': 'fine structure', 'subjectScheme': 'var'}, {'subject': 'hyperfine structure', 'subjectScheme': 'var'}]",,['Radex'],,,"['Cites', 'IsPartOf', 'References', 'References']",
10.18709/perscido.2020.06.ds299,GreEn-ER - Dataset of electricity consumption,PerSciDo,2020,en,Dataset,,Dataset of electricity consumption of the GreEn-ER Building Located in Grenoble,fabrica,True,findable,0,0,0,0,0,2020-06-18T11:27:55.000Z,2020-06-18T11:27:55.000Z,inist.persyval,vcob,"Computer Science,Engineering","[{'lang': 'en', 'subject': 'Computer Science'}, {'lang': 'en', 'subject': 'Engineering'}]",['62.42 MB'],['csv'],,,,
10.26302/sshade/bandlist_abs_c4h2_c4h2-i,Absorption band list of C4H2 in natural solid C4H2 (crystalline phase I),SSHADE/BANDLIST (OSUG Data Center),2023,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 $C_4H_2$ in natural solid $C_4H_2$ (phase I) at 10 and 95 K,mds,True,findable,0,0,0,0,0,2023-04-30T10:23:35.000Z,2023-04-30T10:23:36.000Z,inist.sshade,mgeg,"natural C4H2 - phase I,Diacetylene,Diacetylene phase I,C4H2 Phase I,Buta-1,3-diyne,460-12-8,C4H2,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 C4H2 - phase I', 'subjectScheme': 'name'}, {'subject': 'Diacetylene', 'subjectScheme': 'name'}, {'subject': 'Diacetylene phase I', 'subjectScheme': 'name'}, {'subject': 'C4H2 Phase I', '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': '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'],,,"['IsPartOf', 'IsPartOf', 'IsDerivedFrom', 'Cites', 'IsSourceOf', 'Cites', 'IsSourceOf', 'Cites', 'IsDerivedFrom', 'Cites', 'IsSourceOf', 'Cites', 'IsSourceOf', 'Cites', 'IsDerivedFrom', 'Cites', 'IsSourceOf', 'Cites', 'IsSourceOf', 'Cites']",
10.5061/dryad.5s77q,Data from: Detecting genomic signatures of natural selection with principal component analysis: application to the 1000 Genomes data,Dryad,2015,en,Dataset,Creative Commons Zero v1.0 Universal,"To characterize natural selection, various analytical methods for
detecting candidate genomic regions have been developed. We propose to
perform genome-wide scans of natural selection using principal component
analysis (PCA). We show that the common FST index of genetic
differentiation between populations can be viewed as the proportion of
variance explained by the principal components. Considering the
correlations between genetic variants and each principal component
provides a conceptual framework to detect genetic variants involved in
local adaptation without any prior definition of populations. To validate
the PCA-based approach, we consider the 1000 Genomes data (phase 1)
considering 850 individuals coming from Africa, Asia, and Europe. The
number of genetic variants is of the order of 36 millions obtained with a
low-coverage sequencing depth (3×). The correlations between genetic
variation and each principal component provide well-known targets for
positive selection (EDAR, SLC24A5, SLC45A2, DARC), and also new candidate
genes (APPBPP2, TP1A1, RTTN, KCNMA, MYO5C) and noncoding RNAs. In addition
to identifying genes involved in biological adaptation, we identify two
biological pathways involved in polygenic adaptation that are related to
the innate immune system (beta defensins) and to lipid metabolism (fatty
acid omega oxidation). An additional analysis of European data shows that
a genome scan based on PCA retrieves classical examples of local
adaptation even when there are no well-defined populations. PCA-based
statistics, implemented in the PCAdapt R package and the PCAdapt fast
open-source software, retrieve well-known signals of human adaptation,
which is encouraging for future whole-genome sequencing project,
especially when defining populations is difficult.",mds,True,findable,448,51,1,1,0,2016-01-05T10:16:27.000Z,2016-01-05T10:16:28.000Z,dryad.dryad,dryad,"selection scan,1000 genomes,FST,Principal component analysis","[{'subject': 'selection scan'}, {'subject': '1000 genomes'}, {'subject': 'FST'}, {'subject': 'Principal component analysis', 'schemeUri': 'https://github.com/PLOS/plos-thesaurus', 'subjectScheme': 'PLOS Subject Area Thesaurus'}]",['418982236 bytes'],,,,['IsCitedBy'],
10.26302/sshade/experiment_hm_20170912_101,Optical constants from UV to FIR for cellulose pyrolized between 400 and 1000°C,SSHADE/DOCCD (OSUG Data Center),2018,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,0,0,0,0,0,2020-04-20T13:08:28.000Z,2020-04-20T13:08:29.000Z,inist.sshade,mgeg,"laboratory,organic molecular solid,Cellulose pellet pyrolyzed at 400°C,Cellulose pellet pyrolyzed at 600°C,Cellulose pellet pyrolyzed at 800°C,Cellulose pellet pyrolyzed at 1000°C,laboratory measurement,specular reflection,macroscopic,UV,Ultraviolet,Vis,Visible,NIR,Near-Infrared,MIR,Mid-Infrared,FIR,Far-Infrared,transmission,optical constants","[{'subject': 'laboratory'}, {'subject': 'organic molecular solid'}, {'subject': 'Cellulose pellet pyrolyzed at 400°C'}, {'subject': 'Cellulose pellet pyrolyzed at 600°C'}, {'subject': 'Cellulose pellet pyrolyzed at 800°C'}, {'subject': 'Cellulose pellet pyrolyzed at 1000°C'}, {'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': 'transmission'}, {'subject': 'optical constants'}]",['4 spectra'],['ASCII'],,,"['IsPartOf', 'IsPartOf']",
10.17178/emaa_a-ch3(18o)h_rotation_c65648f1,Rotation excitation of A-CH3[18O]H by ortho-H2 and para-H2 collisions,"UGA, CNRS, CNRS-INSU, OSUG",2023,en,Dataset,"Please acknowledge the use of EMAA Database by citing the original articles in which the data were published (BibTeX format available), and adding the following sentence in your publication:
This research has made use of spectroscopic and collisional data from the EMAA database (https://emaa.osug.fr). EMAA is supported by the Observatoire des Sciences de l'Univers de Grenoble (OSUG),Creative Commons Attribution 4.0 International,Data access and use are ruled by the EMAA data policy.",25 rotation energy levels / 73 radiative transitions / 291 collisional transitions for para-H2 (20 temperatures in the range 10-200K) / 300 collisional transitions for ortho-H2 (20 temperatures in the range 10-200K),mds,True,findable,0,0,0,0,0,2023-12-07T15:50:32.000Z,2023-12-07T15:50:32.000Z,inist.osug,jbru,"target A-CH3[18O]H,excitationType Rotation,collisional excitation,collider.0 para-H2,collider.1 ortho-H2,astrophysics,interstellar medium,comets,circumstellar medium,gas,microwave spectroscopy,infrared spectroscopy,rotational excitation,rovibrational excitation,vibrational excitation,electronic excitation,collisional rate coefficients,fine structure,hyperfine structure","[{'subject': 'target A-CH3[18O]H', 'subjectScheme': 'main'}, {'subject': 'excitationType Rotation', 'subjectScheme': 'main'}, {'subject': 'collisional excitation', 'subjectScheme': 'main'}, {'subject': 'collider.0 para-H2', 'subjectScheme': 'var'}, {'subject': 'collider.1 ortho-H2', 'subjectScheme': 'var'}, {'subject': 'astrophysics', 'subjectScheme': 'var'}, {'subject': 'interstellar medium', 'subjectScheme': 'var'}, {'subject': 'comets', 'subjectScheme': 'var'}, {'subject': 'circumstellar medium', 'subjectScheme': 'var'}, {'subject': 'gas', 'subjectScheme': 'var'}, {'subject': 'microwave spectroscopy', 'subjectScheme': 'var'}, {'subject': 'infrared spectroscopy', 'subjectScheme': 'var'}, {'subject': 'rotational excitation', 'subjectScheme': 'var'}, {'subject': 'rovibrational excitation', 'subjectScheme': 'var'}, {'subject': 'vibrational excitation', 'subjectScheme': 'var'}, {'subject': 'electronic excitation', 'subjectScheme': 'var'}, {'subject': 'collisional rate coefficients', 'subjectScheme': 'var'}, {'subject': 'fine structure', 'subjectScheme': 'var'}, {'subject': 'hyperfine structure', 'subjectScheme': 'var'}]",,['Radex'],,,"['Cites', 'IsPartOf', 'References', 'References']",
10.17178/ohmcv.dsd.pvi.12-16.1,"DSD network, Pradel-Vignes",CNRS - OSUG - OREME,2009,en,Dataset,"Data access and use are ruled by the OHMCV data policy.,The following acknowledging sentence should appear in publications using OHMCV data and products: ""OHMCV is funded by the Institut National des Sciences de l’Univers (INSU/CNRS) and the Observatoire des Sciences de l’Univers de Grenoble (OSUG / Université Grenoble Alpes)”.",This dataset is part of the Cevennes‐Vivarais Mediterranean Hydrometeorological Observatory (OHMCV),mds,True,findable,0,0,2,0,0,2017-10-17T13:24:17.000Z,2017-10-17T13:24:18.000Z,inist.osug,jbru,"Atmospheric conditions,Precipitation Rate,Droplet Size,DISDROMETERS,Ground networks,Hydrometeorological sites,Fixed Observation Stations","[{'subject': 'Atmospheric conditions', 'subjectScheme': 'main'}, {'subject': 'Precipitation Rate', 'subjectScheme': 'main'}, {'subject': 'Droplet Size', 'subjectScheme': 'main'}, {'subject': 'DISDROMETERS', 'subjectScheme': 'main'}, {'subject': 'Ground networks', 'subjectScheme': 'main'}, {'subject': 'Hydrometeorological sites', 'subjectScheme': 'main'}, {'subject': 'Fixed Observation Stations', 'subjectScheme': 'main'}]",,['NETCDF'],,,"['Cites', 'IsPartOf']",
10.18709/perscido.2020.03.ds300,The VLSAT (Very Large SAT) Benchmark Suite,PerSciDo,2020,en,Dataset,Creative Commons Attribution 4.0 International,"The VLSAT benchmark suite (where ""VL"" stands for ""Very Large"") is a collection of one hundred of SAT formulas to be used as benchmarks in scientific experiments and software competitions. These SAT formulas have been obtained from the automatic conversion into Nested-Unit Petri Nets (NUPNs) of a large collection of Petri nets modelling real-life problems, such as communication protocols and concurrent systems.",fabrica,True,findable,0,0,0,1,0,2020-03-11T16:46:55.000Z,2020-03-11T16:46:56.000Z,inist.persyval,vcob,Computer science,"[{'lang': 'en', 'subject': 'Computer science'}]",['500 MB'],['DIMACS CNF'],,,['IsCitedBy'],
10.26302/sshade/experiment_jr_20150621_001,W L3 edge XAS transmission of Tungsten oxydation in biological media,SSHADE/FAME (OSUG Data Center),2022,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,0,0,0,0,0,2022-10-28T13:55:16.000Z,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'],,,"['IsPartOf', 'IsPartOf', 'IsSourceOf']",
10.5281/zenodo.7485724,"Datasets for ""Observation of universal Hall response in strongly interacting Fermions""",Zenodo,2023,,Dataset,"Creative Commons Attribution 4.0 International,Open Access","This submission includes the datasets shown in the figures of journal article ""Observation of universal Hall response in strongly interacting Fermions"" by T.-W. Zhou et al., Science (2023). The naming of the files corresponds to the figure numbering in the published article:<br> FIG-x for figures in the main text<br> FIG-Sxx for figures in the Supplementary Materials",mds,True,findable,0,0,0,0,0,2023-07-13T06:50:55.000Z,2023-07-13T06:50:56.000Z,cern.zenodo,cern,"Hall effect,Quantum simulation,Quantum technologies,Condensed Matter Physics,FOS: Physical sciences,Atomic Physics","[{'subject': 'Hall effect'}, {'subject': 'Quantum simulation'}, {'subject': 'Quantum technologies'}, {'subject': 'Condensed Matter Physics'}, {'subject': 'FOS: Physical sciences', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': 'Atomic Physics'}]",,,,,['HasVersion'],"[['IsVersionOf', '10.5281/zenodo.7485724']]"
10.6084/m9.figshare.16851144,Additional file 5 of The mitochondrially-localized nucleoside diphosphate kinase D (NME4) is a novel metastasis suppressor,figshare,2021,,Audiovisual,Creative Commons Attribution 4.0 International,Additional file 5: Movie 4. Videomicroscopy of kinase-dead NDPK-D mutant HeLa clones.,mds,True,findable,0,0,93,1,0,2021-10-22T04:07:49.000Z,2021-10-22T04:07:51.000Z,figshare.ars,otjm,"Biophysics,Biochemistry,Medicine,Cell Biology,Genetics,FOS: Biological sciences,Molecular Biology,Physiology,Immunology,FOS: Clinical medicine,Developmental Biology,Cancer,Hematology,Infectious Diseases,FOS: Health sciences,Computational Biology","[{'subject': 'Biophysics'}, {'subject': 'Biochemistry'}, {'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': 'Physiology'}, {'subject': 'Immunology'}, {'subject': 'FOS: Clinical medicine', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': 'Developmental Biology'}, {'subject': 'Cancer'}, {'subject': 'Hematology'}, {'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'}]",['7942610 Bytes'],,,,"['References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'IsSupplementTo']",
10.6084/m9.figshare.16786747,Additional file 15 of Open-label randomized controlled trial of ultra-low tidal ventilation without extracorporeal circulation in patients with COVID-19 pneumonia and moderate to severe ARDS: study protocol for the VT4COVID trial,figshare,2021,,Text,Creative Commons Attribution 4.0 International,Additional file 15. Consent form (surrogates).,mds,True,findable,0,0,16,1,0,2021-10-12T04:24:51.000Z,2021-10-12T04:24:52.000Z,figshare.ars,otjm,"Medicine,Cell Biology,Physiology,FOS: Biological sciences,Biotechnology,Cancer,Mental Health,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': 'Biotechnology'}, {'subject': 'Cancer'}, {'subject': 'Mental Health'}, {'subject': 'Computational Biology'}]",['217073 Bytes'],,,,"['IsIdenticalTo', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'IsSupplementTo']","[['IsIdenticalTo', '10.6084/m9.figshare.16786747']]"
10.5281/zenodo.3981251,Ultra-wideband SAR Tomography on asteroids : FDBP and Compressive Sensing datasets,Zenodo,2020,,Dataset,"Creative Commons Attribution 4.0 International,Open Access","Our knowledge of the internal structure of asteroids is currently indirect and relies on inferences from remote sensing observations of surfaces. However, it is fundamental for understanding small bodies’ history and for planetary defense missions. Radar observation of asteroids is the most mature technique available to characterize their inner structure, and Synthetic Aperture Radar Tomography (TomoSAR) allows 3D imaging by extending the synthetic aperture principle in the elevation direction. However, as the geometry of observation of small asteroids is complex, and TomoSAR studies have always been performed in the Earth observation geometry, TomoSAR results in a small body geometry must be simulated to assess the methods’ performances. Different tomography algorithms can be adopted, depending on the characteristics of the problem. While the Frequency Domain Back Projection (FDBP) is based on the correction of the Fourier transform of the received signal by an <em>ad-hoc</em> function built from the geometry of study, it can only retrieve the true position of the scatterers when applied along with ray-tracing methods, which are unreliable in the case of rough asteroid surfaces. Meanwhile, the Compressive Sensing (CS) is based on the compressive sampling theory, which relies on the hypothesis that few scatterers lie in the same direction from the subsurface. The CS can be used to retrieve the position of the scatterers, but its application in the small body geometry is questioned. Thus, both performances of the FDBP and the CS in a small body geometry are demonstrated, and the quality of the reconstruction is analyzed.",mds,True,findable,0,0,0,0,0,2020-08-12T15:57:06.000Z,2020-08-12T15:57:07.000Z,cern.zenodo,cern,,,,,,,['HasVersion'],"[['IsVersionOf', '10.5281/zenodo.3981251']]"
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,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,0,0,0,0,0,2019-11-16T07:51:36.000Z,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'],,,"['IsPartOf', 'IsPartOf']",
10.6084/m9.figshare.16786735,Additional file 11 of Open-label randomized controlled trial of ultra-low tidal ventilation without extracorporeal circulation in patients with COVID-19 pneumonia and moderate to severe ARDS: study protocol for the VT4COVID trial,figshare,2021,,Text,Creative Commons Attribution 4.0 International,Additional file 11. Funding document.,mds,True,findable,0,0,16,1,0,2021-10-12T03:41:31.000Z,2021-10-12T03:41:32.000Z,figshare.ars,otjm,"Medicine,Cell Biology,Physiology,FOS: Biological sciences,Biotechnology,Cancer,Mental Health,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': 'Biotechnology'}, {'subject': 'Cancer'}, {'subject': 'Mental Health'}, {'subject': 'Computational Biology'}]",['578011 Bytes'],,,,"['IsIdenticalTo', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'IsSupplementTo']","[['IsIdenticalTo', '10.6084/m9.figshare.16786735']]"
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,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,0,0,2,1,0,2023-11-10T10:53:00.000Z,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'],,,"['IsPartOf', 'IsPartOf', 'IsSourceOf', 'Cites', 'IsSourceOf', 'Cites', 'IsSourceOf', 'Cites']",
10.5061/dryad.1qt12,"Data from: Extracellular DNA extraction is a fast, cheap and reliable alternative for multi-taxa surveys based on soil DNA",Dryad,2017,en,Dataset,Creative Commons Zero v1.0 Universal,"DNA metabarcoding on soil samples is increasingly used for large-scale and
multi-taxa biodiversity studies. However, DNA extraction may be a major
bottleneck for such wide uses. It should be cost/time effective and allow
dealing with large sample volumes so as to maximise the representativeness
of both micro- and macro-organisms diversity. Here, we compared the
performances of a fast and cheap extracellular DNA extraction protocol
with a total DNA extraction method in retrieving bacterial, eukaryotic and
plant diversity from tropical soil samples of ca. 10 g. The total DNA
extraction protocol yielded more high-quality DNA. Yet, the extracellular
DNA protocol provided similar diversity assessments although it presented
some differences in clades relative abundance and undersampling biases. We
argue that extracellular DNA is a good compromise between cost, labor, and
accuracy for high-throughput DNA metabarcoding studies of soil
biodiversity.",mds,True,findable,342,59,1,1,0,2016-01-20T19:13:51.000Z,2016-01-20T19:13:52.000Z,dryad.dryad,dryad,"multi-taxa,DNA extraction protocol,Soil biodiversity,present,Holocene,Viridiplantae","[{'subject': 'multi-taxa'}, {'subject': 'DNA extraction protocol'}, {'subject': 'Soil biodiversity'}, {'subject': 'present'}, {'subject': 'Holocene'}, {'subject': 'Viridiplantae'}]",['18100397 bytes'],,,,['IsCitedBy'],
10.26302/sshade/experiment_cl_20181202_02,Ion irradiation ($He^+$) of a Lancé meteorite pellet probed by NIR spectroscopy,SSHADE/DAYSY (OSUG Data Center),2018,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 Lancé meteorite pellet, before and after ion irradiation at different doses.",mds,True,findable,0,0,0,0,0,2022-05-27T17:01:51.000Z,2022-05-27T17:01:52.000Z,inist.sshade,mgeg,"extraterrestrial,carbonaceous chondrite,CO,complex organic-mineral mix,matrix Lancé,complex mineral mix,chondrules Lancé,CAIs Lancé,laboratory measurement,bidirectional reflection,macroscopic,NIR,Near-Infrared,reflectance factor","[{'subject': 'extraterrestrial'}, {'subject': 'carbonaceous chondrite'}, {'subject': 'CO'}, {'subject': 'complex organic-mineral mix'}, {'subject': 'matrix Lancé'}, {'subject': 'complex mineral mix'}, {'subject': 'chondrules Lancé'}, {'subject': 'CAIs Lancé'}, {'subject': 'laboratory measurement'}, {'subject': 'bidirectional reflection'}, {'subject': 'macroscopic'}, {'subject': 'NIR'}, {'subject': 'Near-Infrared'}, {'subject': 'reflectance factor'}]",['5 spectra'],['ASCII'],,,"['IsPartOf', 'IsPartOf', 'IsSourceOf']",
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,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,0,0,0,0,0,2019-11-15T20:23:12.000Z,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'],,,"['IsPartOf', 'IsPartOf', 'IsSourceOf']",
10.17178/emaa_hcn_rotation_a4d98833,"Rotation excitation of HCN by He, electron, ortho-H2 and para-H2 collisions","UGA, CNRS, CNRS-INSU, OSUG",2021,en,Dataset,"Please acknowledge the use of EMAA Database by citing the original articles in which the data were published (BibTeX format available), and adding the following sentence in your publication:
This research has made use of spectroscopic and collisional data from the EMAA database (https://emaa.osug.fr). EMAA is supported by the Observatoire des Sciences de l'Univers de Grenoble (OSUG),Creative Commons Attribution 4.0 International,Data access and use are ruled by the EMAA data policy.",22 rotation energy levels / 21 radiative transitions / 36 collisional transitions for electron (12 temperatures in the range 10-1000K) / 231 collisional transitions for He (25 temperatures in the range 5-500K) / 231 collisional transitions for para-H2 (12 temperatures in the range 5-500K) / 231 collisional transitions for ortho-H2 (12 temperatures in the range 5-500K),mds,True,findable,0,0,0,0,0,2021-11-17T14:01:04.000Z,2021-11-17T14:01:05.000Z,inist.osug,jbru,"target HCN,excitationType Rotation,collisional excitation,collider.0 electron,collider.1 He,collider.2 para-H2,collider.3 ortho-H2,astrophysics,interstellar medium,comets,circumstellar medium,gas,microwave spectroscopy,infrared spectroscopy,rotational excitation,rovibrational excitation,vibrational excitation,electronic excitation,collisional rate coefficients,fine structure,hyperfine structure","[{'subject': 'target HCN', 'subjectScheme': 'main'}, {'subject': 'excitationType Rotation', 'subjectScheme': 'main'}, {'subject': 'collisional excitation', 'subjectScheme': 'main'}, {'subject': 'collider.0 electron', 'subjectScheme': 'var'}, {'subject': 'collider.1 He', 'subjectScheme': 'var'}, {'subject': 'collider.2 para-H2', 'subjectScheme': 'var'}, {'subject': 'collider.3 ortho-H2', 'subjectScheme': 'var'}, {'subject': 'astrophysics', 'subjectScheme': 'var'}, {'subject': 'interstellar medium', 'subjectScheme': 'var'}, {'subject': 'comets', 'subjectScheme': 'var'}, {'subject': 'circumstellar medium', 'subjectScheme': 'var'}, {'subject': 'gas', 'subjectScheme': 'var'}, {'subject': 'microwave spectroscopy', 'subjectScheme': 'var'}, {'subject': 'infrared spectroscopy', 'subjectScheme': 'var'}, {'subject': 'rotational excitation', 'subjectScheme': 'var'}, {'subject': 'rovibrational excitation', 'subjectScheme': 'var'}, {'subject': 'vibrational excitation', 'subjectScheme': 'var'}, {'subject': 'electronic excitation', 'subjectScheme': 'var'}, {'subject': 'collisional rate coefficients', 'subjectScheme': 'var'}, {'subject': 'fine structure', 'subjectScheme': 'var'}, {'subject': 'hyperfine structure', 'subjectScheme': 'var'}]",,['Radex'],,,"['Cites', 'IsPartOf', 'References', 'References', 'References', 'References']",
10.26302/sshade/experiment_pa_20180702_001,Mo K edge XAS transmission of molybdenum dioxyde MoO2,SSHADE/FAME (OSUG Data Center),2019,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,0,0,0,0,0,2019-12-16T15:01:57.000Z,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'],,,"['IsPartOf', 'IsPartOf']",
10.26302/sshade/experiment_gm_20220122,Raman spectra of some chlorate minerals,SSHADE/REAP (OSUG Data Center),2022,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,0,0,0,1,0,2022-01-22T15:02:21.000Z,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'],,,"['IsPartOf', 'IsPartOf']",
10.6084/m9.figshare.c.6586643,Digital technologies in routine palliative care delivery: an exploratory qualitative study with health care professionals in Germany,figshare,2023,,Collection,Creative Commons Attribution 4.0 International,"Abstract Objective To explore health care professionals’ (HCPs) perspectives, experiences and preferences towards digital technology use in routine palliative care delivery. Methods HCPs (n = 19) purposively selected from a sample of settings that reflect routine palliative care delivery (i.e. specialized outpatient palliative care, inpatient palliative care, inpatient hospice care in both rural and urban areas of the German states of Brandenburg and Berlin) participated in an explorative, qualitative study using semi-structured interviews. Interview data were analyzed using structured qualitative content analysis. Results Digital technologies are widely used in routine palliative care and are well accepted by HCPs. Central functions of digital technologies as experienced in palliative care are coordination of work processes, patient-centered care, and communication. Especially in outpatient care, they facilitate overcoming spatial and temporal distances. HCPs attribute various benefits to digital technologies that contribute to better coordinated, faster, more responsive, and overall more effective palliative care. Simultaneously, participants preferred technology as an enhancement not replacement of care delivery. HCPs fear that digital technologies, if overused, will contribute to dehumanization and thus significantly reduce the quality of palliative care. Conclusion Digital technology is already an essential part of routine palliative care delivery. While generally perceived as useful by HCPs, digital technologies are considered as having limitations and carrying risks. Hence, their use and consequences must be carefully considered, as they should discreetly complement but not replace human interaction in palliative care delivery.",mds,True,findable,0,0,0,0,0,2023-04-13T12:27:58.000Z,2023-04-13T12:27:58.000Z,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'}]",,,,,"['IsSupplementTo', 'IsIdenticalTo']","[['IsIdenticalTo', '10.6084/m9.figshare.c.6586643']]"
10.6084/m9.figshare.22075664,Supplementary document for Dry powders reflectance model based on enhanced back-scattering: case of hematite α-Fe₂O₃ - 6292687.pdf,Optica Publishing Group,2023,,Text,Creative Commons Attribution 4.0 International,Supplementary model information and results,mds,True,findable,0,0,0,0,0,2023-07-26T13:41:37.000Z,2023-09-01T15:03:20.000Z,figshare.ars,otjm,Uncategorized,[{'subject': 'Uncategorized'}],['14116626 Bytes'],,,,,
10.6084/m9.figshare.12421358,Additional file 2 of Impact of take-home messages written into slide presentations delivered during lectures on the retention of messages and the residents’ knowledge: a randomized controlled study,figshare,2020,,Text,Creative Commons Attribution 4.0 International,Additional file 2. Examples of Multiple Choice Questions.,mds,True,findable,0,0,18,0,0,2020-06-04T03:57:26.000Z,2020-06-04T03:57:27.000Z,figshare.ars,otjm,"Medicine,Sociology,FOS: Sociology,Immunology,FOS: Clinical medicine,Biological Sciences not elsewhere classified,Cancer,Science Policy","[{'subject': 'Medicine'}, {'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': 'Biological Sciences not elsewhere classified'}, {'subject': 'Cancer'}, {'subject': 'Science Policy'}]",['12703 Bytes'],,,,"['References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'IsSupplementTo']",
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,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,0,0,0,0,0,2022-03-10T12:46:33.000Z,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'],,,"['IsPartOf', 'IsPartOf']",
10.6084/m9.figshare.22620895,Additional file 1 of Critically ill severe hypothyroidism: a retrospective multicenter cohort study,figshare,2023,,Text,Creative Commons Attribution 4.0 International,Additional file 1: Figure S1. Flowchart of patient selection from participating ICUs. Table S1. Amount of Missing Data for Each Variable Included in the Analysis. Table S2. Characteristics of Severe Hypothyroidism Patients According to the Presence of a Circulatory Failure at ICU Admission. Table S3. Clinical and Biological Features at ICU Admission according to ICU survival. Table S4. Predictive Patient Factors Associated with 6-month Mortality in Critically ill Adults with Severe Hypothyroidism.,mds,True,findable,0,0,31,1,0,2023-04-13T14:55:40.000Z,2023-04-13T14:55:40.000Z,figshare.ars,otjm,"Medicine,Neuroscience,Pharmacology,Immunology,FOS: Clinical medicine,Cancer","[{'subject': 'Medicine'}, {'subject': 'Neuroscience'}, {'subject': 'Pharmacology'}, {'subject': 'Immunology'}, {'subject': 'FOS: Clinical medicine', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': 'Cancer'}]",['96335 Bytes'],,,,"['References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'IsSupplementTo']",
10.17178/emaa_ortho-(13c)c2h2_rotation_a4239764,Rotation excitation of ortho-c-[13C]C2H2 by He and para-H2 collisions,"UGA, CNRS, CNRS-INSU, OSUG",2023,en,Dataset,"Please acknowledge the use of EMAA Database by citing the original articles in which the data were published (BibTeX format available), and adding the following sentence in your publication:
This research has made use of spectroscopic and collisional data from the EMAA database (https://emaa.osug.fr). EMAA is supported by the Observatoire des Sciences de l'Univers de Grenoble (OSUG),Creative Commons Attribution 4.0 International,Data access and use are ruled by the EMAA data policy.",49 rotation energy levels / 109 radiative transitions / 1176 collisional transitions for para-H2 (9 temperatures in the range 5-120K) / 1176 collisional transitions for He (9 temperatures in the range 5-120K),mds,True,findable,0,0,0,0,0,2023-12-07T15:51:34.000Z,2023-12-07T15:51:35.000Z,inist.osug,jbru,"target ortho-c-[13C]C2H2,excitationType Rotation,collisional excitation,collider.0 para-H2,collider.1 He,astrophysics,interstellar medium,comets,circumstellar medium,gas,microwave spectroscopy,infrared spectroscopy,rotational excitation,rovibrational excitation,vibrational excitation,electronic excitation,collisional rate coefficients,fine structure,hyperfine structure","[{'subject': 'target ortho-c-[13C]C2H2', 'subjectScheme': 'main'}, {'subject': 'excitationType Rotation', 'subjectScheme': 'main'}, {'subject': 'collisional excitation', 'subjectScheme': 'main'}, {'subject': 'collider.0 para-H2', 'subjectScheme': 'var'}, {'subject': 'collider.1 He', 'subjectScheme': 'var'}, {'subject': 'astrophysics', 'subjectScheme': 'var'}, {'subject': 'interstellar medium', 'subjectScheme': 'var'}, {'subject': 'comets', 'subjectScheme': 'var'}, {'subject': 'circumstellar medium', 'subjectScheme': 'var'}, {'subject': 'gas', 'subjectScheme': 'var'}, {'subject': 'microwave spectroscopy', 'subjectScheme': 'var'}, {'subject': 'infrared spectroscopy', 'subjectScheme': 'var'}, {'subject': 'rotational excitation', 'subjectScheme': 'var'}, {'subject': 'rovibrational excitation', 'subjectScheme': 'var'}, {'subject': 'vibrational excitation', 'subjectScheme': 'var'}, {'subject': 'electronic excitation', 'subjectScheme': 'var'}, {'subject': 'collisional rate coefficients', 'subjectScheme': 'var'}, {'subject': 'fine structure', 'subjectScheme': 'var'}, {'subject': 'hyperfine structure', 'subjectScheme': 'var'}]",,['Radex'],,,"['Cites', 'IsPartOf', 'References', 'References']",
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,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,0,0,0,0,0,2022-04-23T08:17:40.000Z,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'],,,"['IsPartOf', 'IsPartOf', 'IsSourceOf']",
10.26302/sshade/experiment_tg_20181312_001,UV-Vis optical indices of 3 oxygenated Tholins films,SSHADE/SPAN (OSUG Data Center),2018,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,0,0,0,0,0,2023-04-20T18:06:18.000Z,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'],,,"['IsPartOf', 'IsPartOf', 'IsSourceOf', 'Cites', 'IsSourceOf', 'Cites', 'IsSourceOf', 'Cites']",
10.6084/m9.figshare.24447574,Additional file 1 of Bacterial survival in radiopharmaceutical solutions: a critical impact on current practices,figshare,2023,,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,0,0,0,0,0,2023-10-27T03:41:27.000Z,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'],,,,"['IsIdenticalTo', 'References', 'References', 'References', 'References']","[['IsIdenticalTo', '10.6084/m9.figshare.24447574']]"
10.6084/m9.figshare.12886132,Additional file 3 of Epidural analgesia in ICU chest trauma patients with fractured ribs: retrospective study of pain control and intubation requirements,figshare,2020,,Text,Creative Commons Attribution 4.0 International,Additional file 3: Table S1. Sensitivity analysis restricted to the 526 patients in ICUs where at least 1 study patient received epidural analgesia.,mds,True,findable,0,0,1,1,0,2020-08-28T04:02:52.000Z,2020-08-28T04:02:55.000Z,figshare.ars,otjm,"Medicine,Cell Biology,Genetics,FOS: Biological sciences,Neuroscience,Immunology,FOS: Clinical medicine,Science Policy,Mental Health,Hematology","[{'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': 'Neuroscience'}, {'subject': 'Immunology'}, {'subject': 'FOS: Clinical medicine', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': 'Science Policy'}, {'subject': 'Mental Health'}, {'subject': 'Hematology'}]",['14213 Bytes'],,,,"['References', 'References', 'IsSupplementTo']",
10.5281/zenodo.10400475,Supplementary Data to journal publication on 'The Foundations of the Patagonian Icefields',Zenodo,2023,en,Dataset,Creative Commons Attribution 4.0 International,Partitioning and comparison of ice discharge estimates from the the Patagonian Icefields comprising associated uncertainties. For further details please refer to the notes in the individual files and/or consult the associated publication entitled 'The Foundations of the Patagonian Icefields' published in Communications Earth & Environment.,api,True,findable,0,0,0,0,0,2023-12-18T09:11:12.000Z,2023-12-18T09:11:13.000Z,cern.zenodo,cern,"Patagonia,icefield,discharge,thickness","[{'subject': 'Patagonia'}, {'subject': 'icefield'}, {'subject': 'discharge'}, {'subject': 'thickness'}]",,,,,['HasVersion'],"[['IsVersionOf', '10.5281/zenodo.10400475']]"
10.18709/perscido.2019.07.ds249,Timeseries of surface elevation maps at Dome C measured by time lapse laserscanning,PerSciDo,2019,,Dataset,,"The surface was scanned at Dome C almost daily for nearly 3 years using the Rugged Laserscan (RLS) developped by L. Arnaud and G. Picard (IGE). The dataset contains maps of surface elevation (DEM) with a resolution of 5 cm over an area of about 150m2. Maps are available at best daily, when enough valid data were acquired. The RLS and the data are described in G. Picard, L. Arnaud, R. Caneil, E. Lefebvre, M. Lamare, Observation of the process of snow accumulation on the Antarctic Plateau by time lapse laserscanning, The Cryosphere, doi:10.5194/tc-2019-4",fabrica,True,findable,0,0,0,0,0,2019-07-02T16:46:31.000Z,2019-07-02T16:46:32.000Z,inist.persyval,vcob,"Environmental Science and Ecology,Glaciology","[{'lang': 'en', 'subject': 'Environmental Science and Ecology'}, {'lang': 'en', 'subject': 'Glaciology'}]",,,,,['IsCitedBy'],
10.5281/zenodo.6506582,"Action Planning Makes Physical Activity More Automatic, Only If it Is Autonomously Regulated: A Moderated Mediation Analysis",Zenodo,2022,,Dataset,"Creative Commons Attribution 4.0 International,Open Access",Dataset used for analysis.,mds,True,findable,0,0,0,0,0,2022-04-29T20:45:18.000Z,2022-04-29T20:45:18.000Z,cern.zenodo,cern,,,,,,,['HasVersion'],"[['IsVersionOf', '10.5281/zenodo.6506582']]"
10.15778/resif.zf2003,Bam Aftershock temporary experiment (RESIF - SISMOB),RESIF - Réseau Sismologique et géodésique Français,2010,en,Other,"Open Access,Creative Commons Attribution 4.0 International",Bam Aftershock temporary experiment,mds,True,findable,0,0,0,1,0,2018-03-01T16:01:26.000Z,2018-03-01T16:01:26.000Z,inist.resif,vcob,"Seismology,Bam,Aftershock,Iran","[{'subject': 'Seismology'}, {'subject': 'Bam'}, {'subject': 'Aftershock'}, {'subject': 'Iran'}]",,,,,['IsCitedBy'],
10.5281/zenodo.10635624,Unite! white paper. A new University open science and innovation governance model and policy for a sustainable world,Unite! Alliance Publications,2023,en,Text,Creative Commons Attribution 4.0 International,"This white paper is a practical tool aimed at contributing to the transition from modern science to open science in universities and European Universities Alliances (EUAs) by 2030. This white paper provides evidence-based policy guidelines for university managers, policymakers, and funders to enhance efficient open science and innovation management at universities. ",api,True,findable,0,0,0,0,2,2024-02-09T10:57:13.000Z,2024-02-09T10:57:13.000Z,cern.zenodo,cern,"open science,open science and innovation management,university governance,open innovation,science and innovation policy,European university alliances","[{'subject': 'open science'}, {'subject': 'open science and innovation management'}, {'subject': 'university governance'}, {'subject': 'open innovation'}, {'subject': 'science and innovation policy'}, {'subject': 'European university alliances'}]",,,,,['HasVersion'],
10.5281/zenodo.5243267,Polish DBnary archive in original Lemon format,Zenodo,2021,pl,Dataset,"Creative Commons Attribution Share Alike 4.0 International,Open Access","The DBnary dataset is an extract of Wiktionary data from many language editions in RDF Format. Until July 1st 2017, the lexical data extracted from Wiktionary was modeled using the lemon vocabulary. This dataset contains the full archive of all DBnary dumps in Lemon format containing lexical information from Polish language edition, ranging from 23rd June 2014 to 1st July 2017. After July 2017, DBnary data has been modeled using the ontolex model and will be available in another Zenodo entry.",mds,True,findable,0,0,0,0,0,2021-08-24T10:56:50.000Z,2021-08-24T10:56:51.000Z,cern.zenodo,cern,"Wiktionary,Lemon,Lexical Data,RDF","[{'subject': 'Wiktionary'}, {'subject': 'Lemon'}, {'subject': 'Lexical Data'}, {'subject': 'RDF'}]",,,,,"['IsDocumentedBy', 'HasVersion', 'IsPartOf']","[['IsVersionOf', '10.5281/zenodo.5243267']]"
10.6084/m9.figshare.20221976,Additional file 3 of Response to PEEP in COVID-19 ARDS patients with and without extracorporeal membrane oxygenation. A multicenter case–control computed tomography study,figshare,2022,,Text,Creative Commons Attribution 4.0 International,Additional file 3: Missing data per variable,mds,True,findable,0,0,27,1,0,2022-07-04T06:41:09.000Z,2022-07-04T06:41:11.000Z,figshare.ars,otjm,"Medicine,Microbiology,FOS: Biological sciences,Cell Biology,Physiology,Immunology,FOS: Clinical medicine,Science Policy","[{'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': 'Cell Biology'}, {'subject': 'Physiology'}, {'subject': 'Immunology'}, {'subject': 'FOS: Clinical medicine', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': 'Science Policy'}]",['16378 Bytes'],,,,"['References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'IsSupplementTo']",
10.5281/zenodo.10886304,"Data from ""Allostery and evolution: a molecular journey throught the structural and dynamical landscape of an enzyme super family.""",Zenodo,2024,,Dataset,Creative Commons Attribution 4.0 International,"This data accompanies the paper entitled Allostery and evolution: a molecular journey throught the structural and dynamical landscape of an enzyme super family.
The zip archive contains:
1- Starting configurations of the proteins after equilibration in PDB format and trajectories of unrestrained molecular dynamics simulations with the positions of the proteins every 100 ps in XTC gromacs format are provided for all systems.
2- The free energy profiles and histograms are provided for all umbrella sampling simulations and the scripts used to run it with gromacs.",api,True,findable,0,0,0,0,1,2024-04-23T09:36:21.000Z,2024-04-23T09:36:21.000Z,cern.zenodo,cern,,,,,,,['HasVersion'],
10.57745/hzdptt,Spin-orbit readout using thin films of topological insulator Sb2Te3 deposited by industrial magnetron sputtering,Recherche Data Gouv,2023,,Dataset,,"Data set of the paper : Spin-orbit readout using thin films of topological insulator Sb2Te3 deposited by industrial magnetron sputtering. This includes Sheet resistance versus temperature, and Hall effect and spin signal with their temperature dependance, measured on SbTe based devices and thin film.",mds,True,findable,85,0,0,0,0,2023-06-20T08:46:44.000Z,2023-07-25T09:15:57.000Z,rdg.prod,rdg,,,,,,,"['HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart']",
10.5281/zenodo.5243188,Italian DBnary archive in original Lemon format,Zenodo,2021,it,Dataset,"Creative Commons Attribution Share Alike 4.0 International,Open Access","The DBnary dataset is an extract of Wiktionary data from many language editions in RDF Format. Until July 1st 2017, the lexical data extracted from Wiktionary was modeled using the lemon vocabulary. This dataset contains the full archive of all DBnary dumps in Lemon format containing lexical information from Italian language edition, ranging from 27th August 2012 to 1st July 2017. After July 2017, DBnary data has been modeled using the ontolex model and will be available in another Zenodo entry.",mds,True,findable,0,0,0,0,0,2021-08-24T10:22:49.000Z,2021-08-24T10:22:49.000Z,cern.zenodo,cern,"Wiktionary,Lemon,Lexical Data,RDF","[{'subject': 'Wiktionary'}, {'subject': 'Lemon'}, {'subject': 'Lexical Data'}, {'subject': 'RDF'}]",,,,,"['IsDocumentedBy', 'HasVersion', 'IsPartOf']","[['IsVersionOf', '10.5281/zenodo.5243188']]"
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,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,0,0,0,0,0,2021-02-22T07:43:09.000Z,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'],,,"['IsPartOf', 'IsPartOf', 'IsSourceOf']",
10.5061/dryad.1jwstqk1p,"Data for: Reproductive tactics, birth timing and the risk-resource trade-off in an income breeder",Dryad,2023,en,Dataset,Creative Commons Zero v1.0 Universal,"In variable environments, habitats that are rich in resources often carry
a higher risk of predation. As a result, natural selection should favour
individuals that balance allocation of time to foraging versus avoiding
predation through an optimal decision-making process that maximises
fitness. The behavioural trade-off between resource acquisition and risk
avoidance is expected to be particularly acute during gestation and
lactation when the energetic demands of reproduction peak. Here, we
investigated how reproductive female roe deer adjust their foraging
activity and habitat use during the birth period to manage this trade-off
compared to non-reproductive juveniles, and how parturition date
constrains individual tactics of risk-resource management. Activity of
reproductive females more than doubled immediately following parturition,
when energy demand is highest. Furthermore, compared to non-reproductive
juveniles, they increased their exposure to risk by using open habitat
more during daytime and ranging closer to roads. However, these
post-partum modifications in behaviour were particularly pronounced in
late-parturient females who adopted a more risk-prone tactic, presumably
to compensate for the growth handicap of their late-born offspring. In
income breeders, individuals that give birth late may be constrained to
trade risk avoidance for foraging during peak allocation to reproduction,
with probable consequences for individual fitness.",mds,True,findable,27,3,0,1,0,2023-10-20T15:40:53.000Z,2023-10-20T15:40:54.000Z,dryad.dryad,dryad,"roe deer,Activity data,Spatial Data,FOS: Biological sciences,FOS: Biological sciences","[{'subject': 'roe deer'}, {'subject': 'Activity data'}, {'subject': 'Spatial Data'}, {'subject': 'FOS: Biological sciences', 'subjectScheme': 'fos'}, {'subject': 'FOS: Biological sciences', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}]",['4063924 bytes'],,,,['IsCitedBy'],
10.5061/dryad.6s5pn,Data from: Investigating the genetics of Bti resistance using mRNA tag sequencing: application on laboratory strains and natural populations of the dengue vector Aedes aegypti,Dryad,2013,en,Dataset,Creative Commons Zero v1.0 Universal,"Mosquito control is often the main method used to reduce
mosquito-transmitted diseases. In order to investigate the genetic basis
of resistance to the bio-insecticide Bacillus thuringiensis subsp.
israelensis (Bti), we used information on polymorphism obtained from cDNA
tag sequences from pooled larvae of laboratory Bti-resistant and
susceptible Aedes aegypti mosquito strains to identify and analyse 1520
single nucleotide polymorphisms (SNPs). Of the 372 SNPs tested, 99.2% were
validated using DNA Illumina GoldenGate® array, with a strong correlation
between the allelic frequencies inferred from the pooled and individual
data (r = 0.85). A total of 11 genomic regions and five candidate genes
were detected using a genome scan approach. One of these candidate genes
showed significant departures from neutrality in the resistant strain at
sequence level. Six natural populations from Martinique Island were
sequenced for the 372 tested SNPs with a high transferability (87%), and
association mapping analyses detected 14 loci associated with Bti
resistance, including one located in a putative receptor for Cry11 toxins.
Three of these loci were also significantly differentiated between the
laboratory strains, suggesting that most of the genes associated with
resistance might differ between the two environments. It also suggests
that common selected regions might harbour key genes for Bti resistance.",mds,True,findable,288,41,1,1,0,2013-06-05T16:30:58.000Z,2013-06-05T16:30:59.000Z,dryad.dryad,dryad,"Genomics/Proteomics,Ecotoxicology,Aedes aegypti","[{'subject': 'Genomics/Proteomics'}, {'subject': 'Ecotoxicology', 'schemeUri': 'https://github.com/PLOS/plos-thesaurus', 'subjectScheme': 'PLOS Subject Area Thesaurus'}, {'subject': 'Aedes aegypti', 'schemeUri': 'https://github.com/PLOS/plos-thesaurus', 'subjectScheme': 'PLOS Subject Area Thesaurus'}]",['165732 bytes'],,,,['IsCitedBy'],
10.6084/m9.figshare.22621187,"Additional file 1 of Promoting HPV vaccination at school: a mixed methods study exploring knowledge, beliefs and attitudes of French school staff",figshare,2023,,Text,Creative Commons Attribution 4.0 International,Additional file 1: Additional Table 1. Teams conducting the PrevHPV program (The PrevHPV Consortium). Additional Table 2. COREQ (COnsolidated criteria for REporting Qualitative research) Checklist. Additional Table 3. STROBE (STrengthening the Reporting of OBservational studies in Epidemiology) Statement — checklist of items that should be included in reports of observational studies. Additional Table 4. Characteristics of the middle schools invited to participate in the study and of those which accepted to participate. Additional Table 5. Additional illustrative verbatim of participants to the focus groups. Additional Table 6. Psychological antecedents of vaccination (5C scale) among participants to the self-administered online questionnaire and by profession. Additional Table 7. Public health topics discussed with pupils by participants to the self-administered online questionnaire and by profession. Additional Table 8. Appropriate period to propose HPV vaccination among pupils according to participants to the self-administered online questionnaire and by profession. Additional Document 1. Self-administered online questionnaire. Additional Document 2. Focus groups’ interview guide. Additional Document 3. Names of the PrevHPV Study Group’s members.,mds,True,findable,0,0,0,0,0,2023-04-13T14:58:32.000Z,2023-04-13T14:58:32.000Z,figshare.ars,otjm,"Medicine,Molecular Biology,Biotechnology,Sociology,FOS: Sociology,69999 Biological Sciences not elsewhere classified,FOS: Biological sciences,Cancer,Science Policy,110309 Infectious Diseases,FOS: Health sciences","[{'subject': 'Medicine'}, {'subject': 'Molecular Biology'}, {'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': 'Cancer'}, {'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)'}]",['77628 Bytes'],,,,"['IsSupplementTo', 'IsIdenticalTo']","[['IsIdenticalTo', '10.6084/m9.figshare.22621187']]"
10.5281/zenodo.4776418,PACT1D/PACT-1D-CALNEX: PACT-1D model version v1 for the CALNEX case study,Zenodo,2021,,Software,Open Access,"We present a new one-dimensional chemistry and transport model which performs surface chemistry based on molecular collisions and chemical conversion, allowing us to add detailed HONO formation chemistry at the ground. The model is called Platform for Atmospheric Chemistry and Transport in 1-Dimension (PACT-1D), which is used here for used CALNEX data interpretation as discussed in Tuite et al 2021 (DOI to follow).",mds,True,findable,0,0,0,0,0,2021-05-20T16:15:44.000Z,2021-05-20T16:25:53.000Z,cern.zenodo,cern,,,,,,,"['IsSupplementTo', 'HasVersion']","[['IsVersionOf', '10.5281/zenodo.4776418']]"
10.5281/zenodo.5763671,Dataset for Spatial Heterogeneity of Uplift Pattern in the Western European Alps Revealed by InSAR Time Series Analysis,Zenodo,2021,,Dataset,"Creative Commons Attribution 4.0 International,Open Access",ZIP file with InSAR raw and smoothed final velocity solution values,mds,True,findable,0,0,0,0,0,2021-12-07T10:30:20.000Z,2021-12-07T10:30:21.000Z,cern.zenodo,cern,"Insar velocities,Western Alps","[{'subject': 'Insar velocities'}, {'subject': 'Western Alps'}]",,,,,"['IsCitedBy', 'HasVersion']","[['IsVersionOf', '10.5281/zenodo.5763671']]"
10.5281/zenodo.10640565,"Dataset for the Paper ""Longevity of Artifacts in Leading Parallel and Distributed Systems Conferences: a Review of the State of the Practice in 2023""",Zenodo,2024,,Dataset,Creative Commons Attribution 4.0 International,"Dataset used for the paper ""Longevity of Artifacts in Leading Parallel and Distributed Systems Conferences: a Review of the State of the Practice in 2023"" submitted at ACM REP'24.
The associated analysis scripts are available on Software-Heritage: https://archive.softwareheritage.org/swh:1:dir:3904795a49327b1e9b7ef1a8aff995b1f94ae6fb;origin=https://github.com/GuilloteauQ/artefact-lifetime;visit=swh:1:snp:9adc667f9fefcb6783df076520ef357231030ad4;anchor=swh:1:rev:ad4d19abb5da12fd6df708bc13e444d834c85dfa",api,True,findable,0,0,0,0,2,2024-02-09T14:40:27.000Z,2024-02-09T14:40:27.000Z,cern.zenodo,cern,,,,,,,"['HasVersion', 'HasVersion']",
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,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,0,0,0,1,0,2019-12-05T09:07:34.000Z,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'],,,"['IsPartOf', 'IsPartOf']",
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,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,0,0,0,0,0,2019-11-15T20:31:46.000Z,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'],,,"['IsPartOf', 'IsPartOf']",
10.17178/amma-catch.pa.h2oflux_snns,"Surface flux dataset (including surface energy, water vapor, and carbon fluxes) in the Niakhar site (Faidherbia-Flux station), Senegal","IRD, CNRS-INSU, OSUG, OMP, OREME",2018,en,Dataset,"Creative Commons Attribution 4.0 International,Data access and use are ruled by the AMMA-CATCH data policy.,For any publication using AMMA-CATCH data, authors are asked to:
Mandatory: cite the reference article and the DOI of the observatory
(1) Galle et al. (2018). AMMA-CATCH a Critical Zone Observatory in West Africa Monitoring a Region in Transition. Vadose Zone Journal, 17 (1), 18006.
(2) AMMA-CATCH (1990). AMMA-CATCH : a hydrological, meteorological and ecological observatory on West Africa. IRD, CNRS-INSU, OSUG, OMP, OREME. doi:10.17178/AMMA-CATCH.all
Optional: cite the DOI of each dataset used.
Co-authorship: depending on the contribution of the data to the scientific results obtained, the authors should either propose co-authorship to the data providers or at least acknowledge their contribution.","Measure components of the local-scale energy budget at 2 levels, above tree canopy (20m) and below tree canopy (4.5m). Obtain forcing and validation data for modeling of soil-vegetation-atmosphere exchanges in agro-silvo-pastoral systems of Sahel. Contribute to the flux station network over the AMMA regional transect.",mds,True,findable,0,0,1,0,0,2022-12-09T16:47:51.000Z,2022-12-09T16:47:52.000Z,inist.osug,jbru,"Land surface exchange, water budget, energy budget, sahelian vegetation, evapo-transpiration, sahelian hydrology,Sahelian climate,Friction Velocity at height 4.5 m,Sensible Heat Flux at height 4.5 m,Sensible Heat Flux at height 20 m,Latent Heat Flux at height 4.5 m,Net Ecosystem Exchange of CO2 at height 4.5 m,Latent Heat Flux at height 20 m,Friction Velocity at height 20 m,Net Ecosystem Exchange of CO2 at height 20 m","[{'subject': 'Land surface exchange, water budget, energy budget, sahelian vegetation, evapo-transpiration, sahelian hydrology', 'subjectScheme': 'main'}, {'subject': 'Sahelian climate', 'subjectScheme': 'main'}, {'subject': 'Friction Velocity at height 4.5 m', 'subjectScheme': 'var'}, {'subject': 'Sensible Heat Flux at height 4.5 m', 'subjectScheme': 'var'}, {'subject': 'Sensible Heat Flux at height 20 m', 'subjectScheme': 'var'}, {'subject': 'Latent Heat Flux at height 4.5 m', 'subjectScheme': 'var'}, {'subject': 'Net Ecosystem Exchange of CO2 at height 4.5 m', 'subjectScheme': 'var'}, {'subject': 'Latent Heat Flux at height 20 m', 'subjectScheme': 'var'}, {'subject': 'Friction Velocity at height 20 m', 'subjectScheme': 'var'}, {'subject': 'Net Ecosystem Exchange of CO2 at height 20 m', 'subjectScheme': 'var'}]",,"['CSV', 'NETCDF', 'O&M 1.0']",,,"['Cites', 'IsPartOf', 'IsPartOf']",
10.5281/zenodo.6886497,Dynamic full-field imaging of rupture radiation: Material contrast governs source mechanism,Zenodo,2022,,Dataset,"Creative Commons Attribution 4.0 International,Open Access",Datasets related to the research article 'Dynamic full-field imaging of rupture radiation: Material contrast governs source mechanism'. <br> A readme with the necessary Matlab code to load the data is included.<br> Tested on Matlab2020b For the analytic rupture radiation simulation code please check the linked github repository.,mds,True,findable,0,0,1,3,0,2022-09-19T12:40:22.000Z,2022-09-19T12:40:22.000Z,cern.zenodo,cern,"laboratory earthquake, rupture nucleation, supershear, bi-material contrast, near-field seismology, ultrafast ultrasound, shear wave imaging","[{'subject': 'laboratory earthquake, rupture nucleation, supershear, bi-material contrast, near-field seismology, ultrafast ultrasound, shear wave imaging'}]",,,,,"['IsSupplementTo', 'IsSupplementTo', 'IsSupplementedBy', 'IsSupplementTo', 'HasVersion']","[['IsVersionOf', '10.5281/zenodo.6886497']]"
10.5281/zenodo.5142590,Bayesian Archetypes: Energy signature inference from national data for statistical definition of buildings archetypes.,Zenodo,2021,en,Software,"Apache License 2.0,Open Access",Energy signature inference from national data for statistical definition of buildings archetypes. This project contains the code and data used for the paper <strong>Bayesian inference of dwellings energy signature at national scale: case of the French residential stock</strong>. It aims to infer energy signature of dwelling categories from national census and consumption data.,mds,True,findable,0,0,0,0,0,2021-09-07T16:49:50.000Z,2021-09-07T16:49:50.000Z,cern.zenodo,cern,"Bayesian Inference,Energy Signature,Urban Energy Modeling,Uncertainties,Open Data","[{'subject': 'Bayesian Inference'}, {'subject': 'Energy Signature'}, {'subject': 'Urban Energy Modeling'}, {'subject': 'Uncertainties'}, {'subject': 'Open Data'}]",,,,,['HasVersion'],"[['IsVersionOf', '10.5281/zenodo.5142590']]"
10.5281/zenodo.5243263,Norwegian DBnary archive in original Lemon format,Zenodo,2021,no,Dataset,"Creative Commons Attribution Share Alike 4.0 International,Open Access","The DBnary dataset is an extract of Wiktionary data from many language editions in RDF Format. Until July 1st 2017, the lexical data extracted from Wiktionary was modeled using the lemon vocabulary. This dataset contains the full archive of all DBnary dumps in Lemon format containing lexical information from Norwegian language edition, ranging from 6th February 2015 to 1st July 2017. After July 2017, DBnary data has been modeled using the ontolex model and will be available in another Zenodo entry.",mds,True,findable,0,0,0,0,0,2021-08-24T10:53:45.000Z,2021-08-24T10:53:46.000Z,cern.zenodo,cern,"Wiktionary,Lemon,Lexical Data,RDF","[{'subject': 'Wiktionary'}, {'subject': 'Lemon'}, {'subject': 'Lexical Data'}, {'subject': 'RDF'}]",,,,,"['IsDocumentedBy', 'HasVersion', 'IsPartOf']","[['IsVersionOf', '10.5281/zenodo.5243263']]"
10.6084/m9.figshare.16851135,Additional file 3 of The mitochondrially-localized nucleoside diphosphate kinase D (NME4) is a novel metastasis suppressor,figshare,2021,,Audiovisual,Creative Commons Attribution 4.0 International,Additional file 3: Movie 2. Videomicroscopy of wild-type NDPK-D HeLa clones.,mds,True,findable,0,0,93,1,0,2021-10-22T04:07:03.000Z,2021-10-22T04:07:05.000Z,figshare.ars,otjm,"Biophysics,Biochemistry,Medicine,Cell Biology,Genetics,FOS: Biological sciences,Molecular Biology,Physiology,Immunology,FOS: Clinical medicine,Developmental Biology,Cancer,Hematology,Infectious Diseases,FOS: Health sciences,Computational Biology","[{'subject': 'Biophysics'}, {'subject': 'Biochemistry'}, {'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': 'Physiology'}, {'subject': 'Immunology'}, {'subject': 'FOS: Clinical medicine', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': 'Developmental Biology'}, {'subject': 'Cancer'}, {'subject': 'Hematology'}, {'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'}]",['6353394 Bytes'],,,,"['IsIdenticalTo', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'IsSupplementTo']","[['IsIdenticalTo', '10.6084/m9.figshare.16851135']]"
10.18709/perscido.2020.04.ds310,TMD-CAPTIMOVE,PerSciDo,2020,en,Dataset,,"This database called ""TMD-CAPTIMOVE"" provides transportation mode labelled data collected by 34 volunteers for a total time duration of around 48 hours. Considered transportation modes are: On-foot (Walking, Stairs, Elevators), Bike, Scooter, Bus, Tram. The number of labels is 11: Still, Walk, Upstairs, Downstairs, Elevator up, Elevator down, Bike, Electric scooter, kick scooter, Bus, Tram. Sensor data are: Acceleration (m/s²), angular rate (°/s), atmospheric pressure (hPa), heart rate (beat per minute (BPM)). The sampling frequency for all data is 32 Hertz.",fabrica,True,findable,0,0,0,0,0,2020-04-10T16:11:40.000Z,2020-04-10T16:11:40.000Z,inist.persyval,vcob,"Computer science,Engineering,Learning","[{'lang': 'en', 'subject': 'Computer science'}, {'lang': 'en', 'subject': 'Engineering'}, {'lang': 'en', 'subject': 'Learning'}]",['500 MB'],['csv'],,,,
10.6084/m9.figshare.12991753,Additional file 1 of Association between Neu5Gc carbohydrate and serum antibodies against it provides the molecular link to cancer: French NutriNet-Santé study,figshare,2020,,Text,Creative Commons Attribution 4.0 International,"Additional file 1: Figure S1. Measurements of anti-Neu5Gc IgG in 120 study cohort by ELISA. Figure S2. Distribution of Neu5Gc intake by food source. Figure S3. Increased levels and diversity of anti-Neu5Gc IgG with higher Neu5Gc intake. Figure S4. Anti-Neu5Gc IgG response in patients with infectious mononucleosis and controls. Figure S5. Characteristics of affinity-purified anti-Neu5Gc antibodies of women 45-60. Figure S6. International cancer risk according to national meat intake. Table S1. Sialic acid content (Neu5Ac and Neu5Gc) in common French food items measured by DMB-HPLC. Table S2. Daily Neu5Gc intake in NutriNet-Santé participants (May 2009 through May 2015) with a minimum of six 24-hour dietary records (total 16,149 participants). Table S3. List of glycans printed on glycan microarray and their characteristics. Table S4. Gcemic index.",mds,True,findable,0,0,0,1,0,2020-09-23T03:27:31.000Z,2020-09-23T03:27:37.000Z,figshare.ars,otjm,"Biochemistry,Neuroscience,Physiology,FOS: Biological sciences,Biotechnology,Chemical Sciences not elsewhere classified,Ecology,Immunology,FOS: Clinical medicine,Mathematical Sciences not elsewhere classified,Cancer,Science Policy,Infectious Diseases,FOS: Health sciences","[{'subject': 'Biochemistry'}, {'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': 'Biotechnology'}, {'subject': 'Chemical Sciences not elsewhere classified'}, {'subject': 'Ecology'}, {'subject': 'Immunology'}, {'subject': 'FOS: Clinical medicine', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': 'Mathematical 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)'}]",['1295476 Bytes'],,,,"['IsIdenticalTo', 'IsSupplementTo']","[['IsIdenticalTo', '10.6084/m9.figshare.12991753']]"
10.17178/emaa_oh_fine_2e526008,Fine excitation of OH by ortho-H2 and para-H2 collisions,"UGA, CNRS, CNRS-INSU, OSUG",2021,en,Dataset,"Please acknowledge the use of EMAA Database by citing the original articles in which the data were published (BibTeX format available), and adding the following sentence in your publication:
This research has made use of spectroscopic and collisional data from the EMAA database (https://emaa.osug.fr). EMAA is supported by the Observatoire des Sciences de l'Univers de Grenoble (OSUG),Creative Commons Attribution 4.0 International,Data access and use are ruled by the EMAA data policy.",20 fine energy levels / 50 radiative transitions / 190 collisional transitions for para-H2 (7 temperatures in the range 10-150K) / 190 collisional transitions for ortho-H2 (7 temperatures in the range 10-150K),mds,True,findable,0,0,0,0,0,2022-02-07T11:25:20.000Z,2022-02-07T11:25:21.000Z,inist.osug,jbru,"target OH,excitationType Fine,collisional excitation,collider.0 para-H2,collider.1 ortho-H2,astrophysics,interstellar medium,comets,circumstellar medium,gas,microwave spectroscopy,infrared spectroscopy,rotational excitation,rovibrational excitation,vibrational excitation,electronic excitation,collisional rate coefficients,fine structure,hyperfine structure","[{'subject': 'target OH', 'subjectScheme': 'main'}, {'subject': 'excitationType Fine', 'subjectScheme': 'main'}, {'subject': 'collisional excitation', 'subjectScheme': 'main'}, {'subject': 'collider.0 para-H2', 'subjectScheme': 'var'}, {'subject': 'collider.1 ortho-H2', 'subjectScheme': 'var'}, {'subject': 'astrophysics', 'subjectScheme': 'var'}, {'subject': 'interstellar medium', 'subjectScheme': 'var'}, {'subject': 'comets', 'subjectScheme': 'var'}, {'subject': 'circumstellar medium', 'subjectScheme': 'var'}, {'subject': 'gas', 'subjectScheme': 'var'}, {'subject': 'microwave spectroscopy', 'subjectScheme': 'var'}, {'subject': 'infrared spectroscopy', 'subjectScheme': 'var'}, {'subject': 'rotational excitation', 'subjectScheme': 'var'}, {'subject': 'rovibrational excitation', 'subjectScheme': 'var'}, {'subject': 'vibrational excitation', 'subjectScheme': 'var'}, {'subject': 'electronic excitation', 'subjectScheme': 'var'}, {'subject': 'collisional rate coefficients', 'subjectScheme': 'var'}, {'subject': 'fine structure', 'subjectScheme': 'var'}, {'subject': 'hyperfine structure', 'subjectScheme': 'var'}]",,['Radex'],,,"['Cites', 'IsPartOf', 'References', 'References']",
10.6084/m9.figshare.24483508,Additional file 1 of 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,,Text,Creative Commons Attribution 4.0 International,Additional file 1. Table S1: Analysis of risk factors for 30-day clinical failure in patients with ESBL-KP bacteremia. Table S2: Matching graph of the propensity score.,mds,True,findable,0,0,0,0,0,2023-11-02T05:00:05.000Z,2023-11-02T05:00:06.000Z,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)'}]",['61375 Bytes'],,,,"['IsIdenticalTo', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References']","[['IsIdenticalTo', '10.6084/m9.figshare.24483508']]"
10.5281/zenodo.4010152,I Sit But I Don't Know Why: Integrating Controlled And Automatic Motivational Precursors Within A Socioecological Approach To Predict Sedentary Behaviors,Zenodo,2020,,Dataset,Creative Commons Attribution 4.0 International,"This file contains the raw dataset analyzed.
Sheet 1 contains scored variables.
Sheet 2 presents a description of the variables. ",mds,True,findable,0,0,0,0,0,2020-09-01T07:15:48.000Z,2020-09-01T07:15:49.000Z,cern.zenodo,cern,,,,,,,['HasVersion'],"[['IsVersionOf', '10.5281/zenodo.4010152']]"
10.5281/zenodo.6532307,Micromagnetics of magnetic chemical modulations in soft-magnetic cylindrical nanowires,Zenodo,2022,en,Dataset,"Creative Commons Attribution 4.0 International,Open Access","Abstract: We analyze the micromagnetics of short longitudinal modulations of a high magnetization material in cylindrical nanowires made of a soft-magnetic material of lower magnetization such as Permalloy, combining magnetic microscopy, analytical modeling and micromagnetic simulations. The mismatch of magnetization induces curling of magnetization around the axis in the modulations, in an attempt to screen the interfacial magnetic charges. The curling angle increases with modulation length, until a plateau is reached with nearly full charge screening for a specific length scale, larger than the dipolar exchange length of any of the two materials. The curling circulation can be switched by the Œrsted field arising from a charge current with typical magnitude 10<sup>12</sup>A/m<sup>2</sup>.",mds,True,findable,0,0,0,0,0,2022-05-09T13:36:09.000Z,2022-05-09T13:36:11.000Z,cern.zenodo,cern,"nanomagnetism, nanowire, micromagnetics, magnetization dynamics, magnetic microscopy","[{'subject': 'nanomagnetism, nanowire, micromagnetics, magnetization dynamics, magnetic microscopy'}]",,,,,['HasVersion'],"[['IsVersionOf', '10.5281/zenodo.6532307']]"
10.26302/sshade/experiment_ml_20171220_001,Zr K edge XAS fluorescence of solution of Zr (5000ppm) in HCl (2.5 wt%) at ambient conditions,SSHADE/FAME (OSUG Data Center),2018,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,0,0,0,0,0,2019-12-05T13:02:46.000Z,2019-12-05T13:02:47.000Z,inist.sshade,mgeg,"laboratory,liquid solution,Solution of Zr (5000ppm) in HCl (2.5 wt%),laboratory measurement,fluorescence emission,None,hard X","[{'subject': 'laboratory'}, {'subject': 'liquid solution'}, {'subject': 'Solution of Zr (5000ppm) in HCl (2.5 wt%)'}, {'subject': 'laboratory measurement'}, {'subject': 'fluorescence emission'}, {'subject': 'None'}, {'subject': 'hard X'}]",['1 spectrum'],['ASCII'],,,"['IsPartOf', 'IsPartOf', 'IsSourceOf']",
10.26302/sshade/experiment_zy_20180207_000,"VIS-NIR reflectance spectra collected during a sublimation experiment with ternary mixtures of CO2 frost, spherical water ice particles and JSC Mars-1 regolith simulant",SSHADE/BYPASS (OSUG Data Center),2023,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.","Four different ternary mixtures of CO2 frost, H2O ice and the JSC Mars-1 regolith simulant were produced and the samples were all submitted to slow sublimation at low temperature and ambient pressure. Multispectral/low-res VIS-NIR reflectance spectra were recorded every 30 minutes.",mds,True,findable,0,0,0,0,0,2023-04-28T13:57:28.000Z,2023-04-28T13:57:29.000Z,inist.sshade,mgeg,"laboratory measurement,biconical reflection,imaging,Vis,Visible,NIR,Near-Infrared,reflectance factor,solid CO2,water ice,Magnetite,Ulvospinel,Anorthite,Olivine,Ferrihydrite,Augite,Orthopyroxenes,solid,laboratory,natural terrestrial,inorganic molecular solid,oxide-hydroxide,tektosilicate,nesosilicate,inosilicate","[{'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': 'Magnetite', 'subjectScheme': 'name'}, {'subject': 'Ulvospinel', 'subjectScheme': 'name'}, {'subject': 'Anorthite', 'subjectScheme': 'name'}, {'subject': 'Olivine', 'subjectScheme': 'name'}, {'subject': 'Ferrihydrite', 'subjectScheme': 'name'}, {'subject': 'Augite', 'subjectScheme': 'name'}, {'subject': 'Orthopyroxenes', 'subjectScheme': 'name'}, {'subject': 'solid', 'subjectScheme': 'family'}, {'subject': 'laboratory', 'subjectScheme': 'origin'}, {'subject': 'natural terrestrial', 'subjectScheme': 'origin'}, {'subject': 'inorganic molecular solid', 'subjectScheme': 'compound type'}, {'subject': 'oxide-hydroxide', 'subjectScheme': 'compound type'}, {'subject': 'tektosilicate', 'subjectScheme': 'compound type'}, {'subject': 'nesosilicate', 'subjectScheme': 'compound type'}, {'subject': 'inosilicate', 'subjectScheme': 'compound type'}]",['48 spectra'],['ASCII'],,,"['IsPartOf', 'IsPartOf', 'IsSourceOf', 'Cites', 'IsSourceOf', 'Cites', 'IsSourceOf', 'Cites']",
10.17178/gnss.products.all,GNSS position and velocity solutions,"CNRS, OSUG, ISTERRE",2019,en,Dataset,"License: CC BY-NC-ND 4.0,Data access and use are ruled by the OSUG data policy.,The following acknowledging sentence should appear in publications using ISTerre GNSS products: ""GNSS products are calculated and provided by the Institut of Sciences de la Terre (ISTerre), belonging to the Institut National des Sciences de l’Univers (INSU/CNRS) and the Observatoire des Sciences de l’Univers de Grenoble (OSUG / Université Grenoble Alpes)"".
You are invited to contact the PI(s) or lead scientist for more information about the data and to include the acknowledgement sentence in any publication using the data.","GNSS data are acquired and/or analyzed by the ISTerre laboratory, part of the Observatory of Earth Sciences and Astronomy of Grenoble (OSUG). GNSS data from permanent sites are processed. Different areas in the world are processed, corresponding to different research projects. ISTerre provides the processing solutions, i.e. position and velocity for each GNSS site. A specific DOI is allocated for those solutions, as well as for RInEx data when relevant.",mds,True,findable,0,0,1,0,0,2019-04-05T10:19:17.000Z,2019-04-05T10:19:17.000Z,inist.osug,jbru,"GNSS products,Velocity field,GNSS data analysis,Time serie positioning","[{'subject': 'GNSS products', 'subjectScheme': 'main'}, {'subject': 'Velocity field', 'subjectScheme': 'var'}, {'subject': 'GNSS data analysis', 'subjectScheme': 'var'}, {'subject': 'Time serie positioning', 'subjectScheme': 'var'}]",,"['pos', 'PBO']",,,"['Cites', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart']",
10.6084/m9.figshare.23816832,Supplementary document for Dry powders reflectance model based on enhanced back-scattering: case of hematite α-Fe₂O₃ - 6551122.pdf,Optica Publishing Group,2023,,Text,Creative Commons Attribution 4.0 International,Supplemental document.,mds,True,findable,0,0,0,0,0,2023-09-01T15:04:45.000Z,2023-09-01T15:04:45.000Z,figshare.ars,otjm,Uncategorized,[{'subject': 'Uncategorized'}],['11379174 Bytes'],,,,['IsIdenticalTo'],"[['IsIdenticalTo', '10.6084/m9.figshare.23816832']]"
10.15778/resif.8c2019,Seismic network 8C :monitoring swarms in the Mont-Blanc and Vallorcine area (RESIF - SISMOB),RESIF - Réseau Sismologique et géodésique Français,2020,en,Dataset,"Open Access,Creative Commons Attribution 4.0 International","We have installed three stations around the Mont-Banc massif in order to detect local earthquakes. These stations were installed at the same location as stations from Cifalp2 project, that were uninstalled in December 219. The goal is to detect and locate earthquakes from several swarms in the area, one along the French-italian border below the « Grandes Jorasses », another one closer to Chamonix, and a third one near Vallorcine. Moreover, these stations may also help to locate seismic signals produced by glacier basal sliding, rockfalls or glacier collapse.",mds,True,findable,0,0,0,1,0,2021-03-03T10:15:16.000Z,2021-03-03T10:15:42.000Z,inist.resif,vcob,"Swarm,icequake,landslide sliding,glacier swarms,Mont-Blanc massif,Courmayeur","[{'subject': 'Swarm'}, {'subject': 'icequake'}, {'subject': 'landslide sliding'}, {'subject': 'glacier swarms'}, {'subject': 'Mont-Blanc massif'}, {'subject': 'Courmayeur'}]","['3 stations, growing']","['Miniseed data', 'stationXML metadata']",,,"['IsCitedBy', 'Obsoletes']",
10.26302/sshade/bandlist_abs_n2_alpha-n2,Absorption band list of N2 in natural solid N2 (phase alpha),SSHADE/BANDLIST (OSUG Data Center),2021,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 absorption band list of the isotopes of $N_2$ in natural solid $\alpha-N2$,mds,True,findable,0,0,0,0,0,2023-04-21T07:12:06.000Z,2023-04-21T07:12:07.000Z,inist.sshade,mgeg,"natural N2 - phase alpha,Nitrogen,Solid alpha Nitrogen,$\alpha$-phase,Dinitrogen,7727-37-9,N2,non polar molecular solid,molecular solids with apolar molecules,inorganic molecular solid,absorption,NIR,MIR,FIR,band frequency,band width,band intensity,transition and vibration modes","[{'subject': 'natural N2 - phase alpha', 'subjectScheme': 'name'}, {'subject': 'Nitrogen', 'subjectScheme': 'name'}, {'subject': 'Solid alpha Nitrogen', 'subjectScheme': 'name'}, {'subject': '$\\alpha$-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': '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'],,,"['IsPartOf', 'IsPartOf', 'IsDerivedFrom', 'Cites', 'IsSourceOf', 'Cites', 'IsSourceOf', 'Cites', 'IsDerivedFrom', 'Cites', 'IsSourceOf', 'Cites', 'IsSourceOf', 'Cites', 'IsDerivedFrom', 'Cites', 'IsSourceOf', 'Cites', 'IsSourceOf', 'Cites', 'IsSourceOf', 'Cites']",
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,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,0,0,0,0,0,2020-05-28T14:06:16.000Z,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'],,,"['IsPartOf', 'IsPartOf', 'IsSourceOf']",
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,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,0,0,0,0,0,2023-04-28T13:53:30.000Z,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'],,,"['IsPartOf', 'IsPartOf', 'IsSourceOf', 'Cites', 'IsSourceOf', 'Cites', 'IsSourceOf', 'Cites']",
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,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,0,0,0,1,0,2020-02-11T11:54:57.000Z,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'],,,"['IsPartOf', 'IsPartOf']",
10.5281/zenodo.5223539,"Input data for PARASO, a circum-Antarctic fully-coupled 5-component model",Zenodo,2021,,Dataset,"Creative Commons Attribution 4.0 International,Open Access","Input data for running the PARASO experiments. These files should be extracted, and the folder containing them should be referred to in the `data.cfg` Coral configuration file. See also PARASO documentation from the PARASO sources. The ERA5 forcings (COSMO boundary files and NEMO surface forcings) are not provided herein as they are too large, but we provide: - scripts for downloading and post-processing the ERA5 NEMO forcings; - INT2LM configuration file, with the new Antarctic geometry, to generate COSMO lateral forcings. A 3-month sample of ERA5 data is also available (see <strong>Forcings</strong> below). <strong>Model description: </strong>Pelletier, C., Fichefet, T., Goosse, H., Haubner, K., Helsen, S., Huot, P.-V., Kittel, C., Klein, F., Le clec'h, S., van Lipzig, N. P. M., Marchi, S., Massonnet, F., Mathiot, P., Moravveji, E., Moreno-Chamarro, E., Ortega, P., Pattyn, F., Souverijns, N., Van Achter, G., Vanden Broucke, S., Vanhulle, A., Verfaillie, D., and Zipf, L.: PARASO, a circum-Antarctic fully coupled ice-sheet–ocean–sea-ice–atmosphere–land model involving f.ETISh1.7, NEMO3.6, LIM3.6, COSMO5.0 and CLM4.5, Geosci. Model Dev., 15, 553–594, 10.5194/gmd-15-553-2022, 2022. <strong>Source code (no COSMO)</strong>: Pelletier, Charles, Klein, François, Zipf, Lars, Haubner, Konstanze, Mathiot, Pierre, Pattyn, Frank, Moravveji, Ehsan, & Vanden Broucke, Sam. (2021). PARASO source code (no COSMO) (v1.4.3). Zenodo. 10.5281/zenodo.5576201 <strong>Forcings: </strong>Pelletier, Charles, & Helsen, Samuel. (2021). PARASO ERA5 forcings (1.4.3) [Data set]. Zenodo. 10.5281/zenodo.5590053<br> <strong>Acknowledgements</strong> <strong>ORAS5: </strong>Zuo, H, Alonso-Balmaseda, M, Mogensen, K, Tietsche, S: OCEAN5: The ECMWF Ocean Reanalysis System and its Real-Time analysis component. 2018. 10.21957/la2v0442 downloaded from the ICDC (University of Hamburg) on 01-SEP-2019. <em>(The results contain modified Copernicus Climate Change Service information 2020. Neither the European Commission nor ECMWF is responsible for any use that may be made of the Copernicus information or data it contains.)</em> <strong>BedMachine: </strong>Morlighem, M. 2020. <em>MEaSUREs BedMachine Antarctica, Version 2</em>. Ice-shelf Boulder, Colorado USA. NASA National Snow and Ice Data Center Distributed Active Archive Center. doi: 10.5067/E1QL9HFQ7A8M. Accessed 01-DEC-2019. Morlighem, M., E. Rignot, T. Binder, D. D. Blankenship, R. Drews, G. Eagles, O. Eisen, F. Ferraccioli, R. Forsberg, P. Fretwell, V. Goel, J. S. Greenbaum, H. Gudmundsson, J. Guo, V. Helm, C. Hofstede, I. Howat, A. Humbert, W. Jokat, N. B. Karlsson, W. Lee, K. Matsuoka, R. Millan, J. Mouginot, J. Paden, F. Pattyn, J. L. Roberts, S. Rosier, A. Ruppel, H. Seroussi, E. C. Smith, D. Steinhage, B. Sun, M. R. van den Broeke, T. van Ommen, M. van Wessem, and D. A. Young. 2020. Deep glacial troughs and stabilizing ridges unveiled beneath the margins of the Antarctic ice sheet, <em>Nature Geoscience</em>. 13. 132-137. 10.1038/s41561-019-0510-8 <strong>Iceberg forcings: </strong>Jourdain, Nicolas C., Merino, Nacho, Le Sommer, Julien, Durand, Gaël, & Mathiot, Pierre. (2019). Interannual iceberg meltwater fluxes over the Southern Ocean (1.0) [Data set]. <em>Zenodo</em>. 10.5281/zenodo.3514728 Merino N., Jourdain, N. C., Le Sommer, J., Goose, H., Mathiot, P. and Durand, G (2018). Impact of increasing Antarctic glacial freshwater release on regional sea-ice cover in the Southern Ocean. <em>Ocean Modelling</em>, 121, 76-89. 10.1016/j.ocemod.2017.11.009",mds,True,findable,0,0,5,9,0,2021-10-27T12:20:30.000Z,2021-10-27T12:20:31.000Z,cern.zenodo,cern,,,,,,,"['Cites', 'IsCitedBy', 'IsSupplementedBy', 'IsSupplementTo', 'Cites', 'Cites', 'Cites', 'Cites', 'Cites', 'HasVersion', 'HasVersion']","[['IsVersionOf', '10.5281/zenodo.5223539']]"
10.17178/cryobsclim.cdp.2018.solarmask,"Col de Porte, Solar Mask",CNRS - OSUG - Meteo France,1998,en,Dataset,"Data access and use are ruled by the CRYOBS-CLIM data policy.,Always quote below citation to Lejeune et al. (2019) when using data.
Lejeune, Y., Dumont, M., Panel J.-M., Lafaysse, M., Lapalus, P., Le Gac, E., Lesaffre, B. and Morin, S., 57 years (1960-2017) of snow and meteorological observations from a mid-altitude mountain site (Col de Porte, France, 1325 m alt.), Earth System Science Data, 11(2019), 71-88, https://doi.org/10.5194/essd-11-71-2019. The following acknowledging sentence should appear in publications using Cryobs-Clim-CDP data and products: ""Cryobs-Clim Col de Porte is funded by Meteo France, the Institut National des Sciences de l’Univers (INSU/CNRS), and the Observatoire des Sciences de l’Univers de Grenoble (OSUG / Université Grenoble Alpes)”. You are invited to contact the PI(s) or lead scientist for more information about the data and to include the acknowledgement sentence in any publication using the data.","This dataset is part of the Cryobs-Clim-CDP (CRYosphere, an OBServatory of the CLIMate – Col de Porte) observatory",mds,True,findable,0,0,1,0,0,2018-07-19T07:26:39.000Z,2018-07-19T07:28:08.000Z,inist.osug,jbru,Solar Mask,"[{'subject': 'Solar Mask', 'subjectScheme': 'main'}]",,['CSV'],,,"['Cites', 'IsPartOf']",
10.6084/m9.figshare.22027566,Students’ and tutors’ experiences of remote ‘student–patient’ consultations,Taylor & Francis,2023,,Text,Creative Commons Attribution 4.0 International,"Remote consulting has become part of the medical student clinical experience in primary care, but little research exists regarding the impact on learning. To describe the experiences of General Practitioner (GP) educators and medical students in using student-led remote consultations as an educational tool. A qualitative, explorative study conducted at four UK medical schools. GP educators and medical students were purposively sampled and interviewed. Nine themes arose: practical application, autonomy, heuristics, safety, triage of undifferentiated patients, clinical reasoning, patient inclusion in student education, student–patient interaction, and student–doctor interaction. Remote consulting has become part of the clinical placement experience. This has been found to expose students to a wider variety of clinical presentations. Verbal communication, history-taking, triage, and clinical reasoning skills were practised through remote consulting, but examination skills development was lacking. Students found building rapport more challenging, although this was mitigated by having more time with patients. Greater clinical risk was perceived in remote consulting, which had potential to negatively impact students’ psychological safety. Frequent debriefs could ameliorate this risk and positively impact student–doctor relationships. Student autonomy and independence increased due to greater participation and responsibility. Pre-selection of patients could be helpful but had potential to expose students to lower complexity patients. Practice pointsRemote consulting confers unique educational benefits.Remote consulting can help develop history-taking and communication skills, as well as clinical reasoning skills.The psychological safety of the student and the supervisory risk of the tutor can be impacted by remote consulting, but frequent debriefs between the student and tutor can help mitigate this risk.Learning how to conduct remote, and face-to-face consultations is important in medical education. Practice points Remote consulting confers unique educational benefits. Remote consulting can help develop history-taking and communication skills, as well as clinical reasoning skills. The psychological safety of the student and the supervisory risk of the tutor can be impacted by remote consulting, but frequent debriefs between the student and tutor can help mitigate this risk. Learning how to conduct remote, and face-to-face consultations is important in medical education.",mds,True,findable,0,0,0,1,0,2023-02-06T19:20:05.000Z,2023-02-06T19:20:05.000Z,figshare.ars,otjm,"Medicine,Neuroscience,Biotechnology,Science Policy,Mental Health,Hematology,Plant Biology,FOS: Biological sciences","[{'subject': 'Medicine'}, {'subject': 'Neuroscience'}, {'subject': 'Biotechnology'}, {'subject': 'Science Policy'}, {'subject': 'Mental Health'}, {'subject': 'Hematology'}, {'subject': 'Plant Biology'}, {'subject': 'FOS: Biological sciences', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}]",['17511 Bytes'],,,,['IsSupplementTo'],
10.18709/perscido.2016.11.ds08,Three months sample of Ontology-based student monitoring extracted from the national evaluation system of French Medical Schools,PerSciDo,2016,en,Dataset,Creative Commons Attribution Non Commercial No Derivatives 4.0 International,"This dataset contains a sample of student working session on SIDES platform from April to September 2015: 316803 actions of answer to tests on ECN items for 936 students. The dataset is modeled using RDF paradigm, based on the schema of OntoSides ontology.",api,True,findable,0,0,0,0,0,2017-11-03T01:12:24.000Z,2017-11-03T01:12:24.000Z,inist.persyval,vcob,"Computer Science,Medicine","[{'lang': 'en', 'subject': 'Computer Science'}, {'lang': 'en', 'subject': 'Medicine'}]",['500 MB'],"['ttl', 'pdf']",,,,
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,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,0,0,0,0,0,2022-11-04T08:24:14.000Z,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'],,,"['IsPartOf', 'IsPartOf']",
10.5061/dryad.j6q573n7x,Continued adaptation of C4 photosynthesis after an initial burst of changes in the Andropogoneae grasses,Dryad,2019,en,Dataset,Creative Commons Zero v1.0 Universal,"C4 photosynthesis is a complex trait that sustains fast growth and high
productivity in tropical and subtropical conditions and evolved repeatedly
in flowering plants. One of the major C4 lineages is Andropogoneae, a
group of ~ 1,200 grass species that includes some of the world's most
important crops and species dominating tropical and some temperate
grasslands. Previous efforts to understand C4 evolution in the group have
compared a few model C4 plants to distantly related C3 species, so that
changes directly responsible for the transition to C4 could not be
distinguished from those that preceded or followed it. In this study, we
analyse the genomes of 66 grass species, capturing the earliest
diversification within Andropogoneae as well as their C3 relatives.
Phylogenomics combined with molecular dating and analyses of protein
evolution show that many changes linked to the evolution of C4
photosynthesis in Andropogoneae happened in the Early Miocene, between 21
and 18 Ma, after the split from its C3 sister lineage, and before the
diversification of the group. This initial burst of changes was followed
by an extended period of modifications to leaf anatomy and biochemistry
during the diversification of Andropogoneae, so that a single C4 origin
gave birth to a diversity of C4 phenotypes during 18 million years of
speciation events and migration across geographic and ecological spaces.
Our comprehensive approach and broad sampling of the diversity in the
group reveals that one key transition can lead to a plethora of phenotypes
following sustained adaptation of the ancestral state.",mds,True,findable,396,71,0,1,0,2019-10-11T12:58:01.000Z,2019-10-11T12:58:02.000Z,dryad.dryad,dryad,"adaptive evolution,Herbarium Genomics,Jansenelleae,leaf anatomy","[{'subject': 'adaptive evolution'}, {'subject': 'Herbarium Genomics'}, {'subject': 'Jansenelleae'}, {'subject': 'leaf anatomy'}]",['5622932 bytes'],,,,['IsCitedBy'],
10.5281/zenodo.8269854,Heterogeneous/Homogeneous Change Detection dataset,Zenodo,2023,en,Dataset,Creative Commons Attribution 4.0 International,"""Please if you use this datasets we appreciated that you reference this repository and cite the works related that made possible the generation of this dataset.""
This change detection datastet has different events, satellites, resolutions and includes both homogeneous/heterogeneous cases. The main idea of the dataset is to bring a benchmark on semantic change detection in remote sensing field.This dataset is the outcome of the following publications:
@article{ JimenezSierra2022graph,author={Jimenez-Sierra, David Alejandro and Quintero-Olaya, David Alfredo and Alvear-Mu{\~n}oz, Juan Carlos and Ben{\'i}tez-Restrepo, Hern{\'a}n Dar{\'i}o and Florez-Ospina, Juan Felipe and Chanussot, Jocelyn},journal={IEEE Transactions on Geoscience and Remote Sensing},title={Graph Learning Based on Signal Smoothness Representation for Homogeneous and Heterogeneous Change Detection},year={2022},volume={60},number={},pages={1-16},doi={10.1109/TGRS.2022.3168126}}
@article{ JimenezSierra2020graph,title={Graph-Based Data Fusion Applied to: Change Detection and Biomass Estimation in Rice Crops},author={Jimenez-Sierra, David Alejandro and Ben{\'i}tez-Restrepo, Hern{\'a}n Dar{\'i}o and Vargas-Cardona, Hern{\'a}n Dar{\'i}o and Chanussot, Jocelyn},journal={Remote Sensing},volume={12},number={17},pages={2683},year={2020},publisher={Multidisciplinary Digital Publishing Institute},doi={10.3390/rs12172683}}
@inproceedings{jimenez2021blue,title={Blue noise sampling and Nystrom extension for graph based change detection},author={Jimenez-Sierra, David Alejandro and Ben{\'\i}tez-Restrepo, Hern{\'a}n Dar{\'\i}o and Arce, Gonzalo R and Florez-Ospina, Juan F},booktitle={2021 IEEE International Geoscience and Remote Sensing Symposium IGARSS},ages={2895--2898},year={2021},organization={IEEE},doi={10.1109/IGARSS47720.2021.9555107}}
@article{florez2023exploiting,title={Exploiting variational inequalities for generalized change detection on graphs},author={Florez-Ospina, Juan F and Jimenez Sierra, David A and Benitez-Restrepo, Hernan D and Arce, Gonzalo},journal={IEEE Transactions on Geoscience and Remote Sensing}, year={2023},volume={61},number={},pages={1-16},doi={10.1109/TGRS.2023.3322377}}
@article{florez2023exploitingxiv,title={Exploiting variational inequalities for generalized change detection on graphs},author={Florez-Ospina, Juan F. and Jimenez-Sierra, David A. and Benitez-Restrepo, Hernan D. and Arce, Gonzalo R},year={2023},publisher={TechRxiv},doi={10.36227/techrxiv.23295866.v1}}
In the table on the html file (dataset_table.html) are tabulated all the metadata and details related to each case within the dasetet. The cases with a link, were gathered from those sources and authors, therefore you should refer to their work as well.
The rest of the cases or events (without a link), were obtained through the use of open sources such as:
Copernicus
European Space Agency
Alaska Satellite Facility (Vertex)
Earth Data
In addition, we carried out all the processing of the images by using the SNAP toolbox from the European Space Agency. This proccessing involves the following:
Data co-registration
Cropping
Apply Orbit (for SAR data)
Calibration (for SAR data)
Speckle Filter (for SAR data)
Terrain Correction (for SAR data)
Lastly, the ground truth was obtained from homogeneous images for pre/post events by drawing polygons to highlight the areas where a visible change was present. The images where layout and synchorized to be zoomed over the same are to have a better view of changes. This was an exhaustive work in order to be precise as possible.Feel free to improve and contribute to this dataset.",api,True,findable,0,0,0,0,0,2023-11-05T15:26:39.000Z,2023-11-05T15:26:39.000Z,cern.zenodo,cern,"Remote sensing,Change Detection,Multi-Spectral,SAR","[{'subject': 'Remote sensing'}, {'subject': 'Change Detection'}, {'subject': 'Multi-Spectral'}, {'subject': 'SAR'}]",,,,,"['IsDerivedFrom', 'IsDerivedFrom', 'IsDerivedFrom', 'IsDerivedFrom', 'IsDerivedFrom', 'HasVersion']","[['IsVersionOf', '10.5281/zenodo.8269854']]"
10.6084/m9.figshare.12886129,Additional file 2 of Epidural analgesia in ICU chest trauma patients with fractured ribs: retrospective study of pain control and intubation requirements,figshare,2020,,Text,Creative Commons Attribution 4.0 International,Additional file 2: Figure S2. Proportions of patients given epidural analgesia in each study ICU.,mds,True,findable,0,0,1,1,0,2020-08-28T04:02:56.000Z,2020-08-28T04:02:57.000Z,figshare.ars,otjm,"Medicine,Cell Biology,Genetics,FOS: Biological sciences,Neuroscience,Immunology,FOS: Clinical medicine,Science Policy,Mental Health,Hematology","[{'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': 'Neuroscience'}, {'subject': 'Immunology'}, {'subject': 'FOS: Clinical medicine', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': 'Science Policy'}, {'subject': 'Mental Health'}, {'subject': 'Hematology'}]",['14048 Bytes'],,,,"['IsIdenticalTo', 'References', 'References', 'IsSupplementTo']","[['IsIdenticalTo', '10.6084/m9.figshare.12886129']]"
10.6084/m9.figshare.16786759,Additional file 3 of Open-label randomized controlled trial of ultra-low tidal ventilation without extracorporeal circulation in patients with COVID-19 pneumonia and moderate to severe ARDS: study protocol for the VT4COVID trial,figshare,2021,,Text,Creative Commons Attribution 4.0 International,Additional file 3. WHO Trial Registration Dataset.,mds,True,findable,0,0,16,1,0,2021-10-12T03:42:01.000Z,2021-10-12T03:42:02.000Z,figshare.ars,otjm,"Medicine,Cell Biology,Physiology,FOS: Biological sciences,Biotechnology,Cancer,Mental Health,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': 'Biotechnology'}, {'subject': 'Cancer'}, {'subject': 'Mental Health'}, {'subject': 'Computational Biology'}]",['29546 Bytes'],,,,"['References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'IsSupplementTo']",
10.5281/zenodo.10229533,Research compendium to reproduce analyses and figures of the article: Interspecific interactions influence bird population responses to global changes by Gaüzère et al. submitted in Ecology Letters,Zenodo,2023,,Software,Creative Commons Attribution 4.0 International,"Research compendium to reproduce analyses and figures of the article:
_Interspecific interactions influence bird population responses to global changes_
by Gaüzère _et al._ submitted in _Ecology Letters_
#' Compendium authors
#' @author Pierre Gaüzère, \email{pierre.gauzere@@gmail.com},
## General
This repository is structured as follow:
- `data/`: contains data required to reproduce figures and tables
- `analyses/`: contains scripts organized sequentially. prepare data -> run model -> vizualize model outputs -> ..
- `outputs/`: follows the structure of analyses. Contains intermediate numeric
results used to produce the figures
- `figures_tables/`: Contains the figures of the paper
## Figures & tables
Figures will be stored in `figures_tables/`.
Tables will be stored in `outputs/`.",api,True,findable,0,0,0,0,0,2023-11-30T15:03:08.000Z,2023-11-30T15:03:08.000Z,cern.zenodo,cern,,,,,,,['HasVersion'],
10.60527/gx2t-a525,"Evolution des schèmes organisateurs, présentation de l’information et identités sociales des internautes","Univ. Grenoble Alpes, GRESEC",2015,fr,Audiovisual,Droit commun de la propriété intellectuelle,"Intervention de Gérald LACHAUD : Doctorant, ELICO Lyon3. Le 4 mai 2015 à l'Institut de la Communication et des Médias (Université Stendhal Grenoble 3). Communication au colloque international ""La communication numérique au cœur des sociétés : dispositifs, logiques de développement et pratiques"". ",api,True,findable,0,0,0,0,0,2024-03-06T22:51:00.000Z,2024-03-06T22:51:00.000Z,fmsh.prod,fmsh,"Sciences de l'information et de la communication,Communication","[{'subject': ""Sciences de l'information et de la communication""}, {'subject': 'Communication'}]",,['video/mp4'],,,['IsPartOf'],
10.5281/zenodo.7499313,VIP: A Python package for high-contrast imaging,Zenodo,2023,,Software,"Creative Commons Attribution 4.0 International,Open Access","VIP is a Python package providing the tools to reduce, post-process and analyze high-contrast imaging datasets, enabling the detection and characterization of directly imaged exoplanets, circumstellar disks, and stellar environments. VIP is a collaborative project which started at the University of Liège, aiming to integrate open-source, efficient, easy-to-use and well-documented implementations of state-of-the-art algorithms used in the context of high-contrast imaging.",mds,True,findable,0,0,0,0,0,2023-01-02T13:57:10.000Z,2023-01-02T13:57:11.000Z,cern.zenodo,cern,"Python,astronomy,exoplanets,high-contrast,direct imaging","[{'subject': 'Python'}, {'subject': 'astronomy'}, {'subject': 'exoplanets'}, {'subject': 'high-contrast'}, {'subject': 'direct imaging'}]",,,,,['HasVersion'],"[['IsVersionOf', '10.5281/zenodo.7499313']]"
10.17178/ohmcv.dsd.pvi.11-14.1,"DSD network, Pradel-Vignes",CNRS - OSUG - OREME,2009,en,Dataset,"Data access and use are ruled by the OHMCV data policy.,The following acknowledging sentence should appear in publications using OHMCV data and products: ""OHMCV is funded by the Institut National des Sciences de l’Univers (INSU/CNRS) and the Observatoire des Sciences de l’Univers de Grenoble (OSUG / Université Grenoble Alpes)”.",This dataset is part of the Cevennes‐Vivarais Mediterranean Hydrometeorological Observatory (OHMCV),mds,True,findable,0,0,1,1,0,2017-03-10T17:09:20.000Z,2017-03-10T17:09:21.000Z,inist.osug,jbru,"Atmospheric conditions,Precipitation Rate,Droplet Size,DISDROMETERS,Ground networks,Hydrometeorological sites,Fixed Observation Stations","[{'subject': 'Atmospheric conditions', 'subjectScheme': 'main'}, {'subject': 'Precipitation Rate', 'subjectScheme': 'main'}, {'subject': 'Droplet Size', 'subjectScheme': 'main'}, {'subject': 'DISDROMETERS', 'subjectScheme': 'main'}, {'subject': 'Ground networks', 'subjectScheme': 'main'}, {'subject': 'Hydrometeorological sites', 'subjectScheme': 'main'}, {'subject': 'Fixed Observation Stations', 'subjectScheme': 'main'}]",,['NETCDF'],,,"['Cites', 'IsSupplementedBy', 'IsPartOf']",
10.5281/zenodo.5237574,French DBnary archive in original Lemon format,Zenodo,2021,fr,Dataset,"Creative Commons Attribution Share Alike 4.0 International,Open Access","The DBnary dataset is an extract of Wiktionary data from many language editions in RDF Format. Until July 1st 2017, the lexical data extracted from Wiktionary was modeled using the lemon vocabulary. This dataset contains the full archive of all DBnary dumps in Lemon format containing lexical information from French language edition, ranging from 27th August 2012 to 1st July 2017. After July 2017, DBnary data has been modeled using the ontolex model and will be available in another Zenodo entry.<br>",mds,True,findable,0,0,0,0,0,2021-08-24T07:05:18.000Z,2021-08-24T07:05:19.000Z,cern.zenodo,cern,"Wiktionary,Lemon,Lexical Data,RDF","[{'subject': 'Wiktionary'}, {'subject': 'Lemon'}, {'subject': 'Lexical Data'}, {'subject': 'RDF'}]",,,,,"['IsDocumentedBy', 'HasVersion', 'IsPartOf']","[['IsVersionOf', '10.5281/zenodo.5237574']]"
10.17178/draixbleone_gal_ain_dsd_1920,"Drop Size Distribution (DSD) at Ainac (Lat : 44,21492 ; Lon : 6,21085)",IGE - CNRS - OSUG,2020,en,Dataset,"Creative Commons Attribution 4.0 International,The following acknowledging sentence should appear in publications using data and products from the Galabre watershed of the Draix Bleone Observatory: ""DRAIX BLEONE is funded by the Institut National des Sciences de l’Univers (INSU/CNRS) and the Observatoire des Sciences de l’Univers de Grenoble (OSUG / Université Grenoble Alpes)”.,Always quote below citation to Legout et al. (submitted) when using these data. Legout C., Freche G., Biron R., Esteves M., Nord G, Navratil O., Uber M., Grangeon T., Hachgenei N., Boudevillain B. Voiron C., Spadini L. A critical zone observatory dedicated to suspended sediment transport: the meso-scale Galabre catchment (southern French Alps), submitted to Hydrological Processes.",This DSD data set is part of the DRAIXBLEONE_GAL observatory.,mds,True,findable,0,0,0,0,0,2020-09-15T15:58:31.000Z,2020-09-15T15:58:32.000Z,inist.osug,jbru,"Mediterranean mountainous climate,Precipitation,Meteorology","[{'subject': 'Mediterranean mountainous climate', 'subjectScheme': 'main'}, {'subject': 'Precipitation', 'subjectScheme': 'var'}, {'subject': 'Meteorology', 'subjectScheme': 'var'}]",,['CSV'],,,"['Cites', 'IsPartOf']",
10.17178/amma-catch.ce.wchem_od,"Water chemistry dataset (geochemical composition of water), within the Donga watershed (600 km2), Benin","IRD, CNRS-INSU, OSUG, OMP, OREME",2002,en,Dataset,"Creative Commons Attribution 4.0 International,Data access and use are ruled by the AMMA-CATCH data policy.,For any publication using AMMA-CATCH data, authors are asked to:
Mandatory: cite the reference article and the DOI of the observatory
(1) Galle et al. (2018). AMMA-CATCH a Critical Zone Observatory in West Africa Monitoring a Region in Transition. Vadose Zone Journal, 17 (1), 18006.
(2) AMMA-CATCH (1990). AMMA-CATCH : a hydrological, meteorological and ecological observatory on West Africa. IRD, CNRS-INSU, OSUG, OMP, OREME. doi:10.17178/AMMA-CATCH.all
Optional: cite the DOI of each dataset used.
Co-authorship: depending on the contribution of the data to the scientific results obtained, the authors should either propose co-authorship to the data providers or at least acknowledge their contribution.","Identification of the chemical signature of the different compartments (surface runoff, sub-surface, deep water-tables) contributing to river flow. Hydrograph decomposition by mixing models based on chemical signatures of each compartment involved in stream flow production.",mds,True,findable,0,0,2,1,0,2018-03-16T15:37:08.000Z,2018-03-16T15:37:08.000Z,inist.osug,jbru,"Water chemical composition,Sudanian climate,pH,Nickel,Calcium Ion,Silicon,Vanadium,Boron,Magnesium Ion,Water Temperature,Lead,Arsenic,delta Oxygen-18,Conductivity,Uranium,Aluminium,Chloride Ion,Nitrate Ion,Cobalt,Zinc,delta Deuterium,Potassium Ion,Copper,Rubidium,Lithium,Sulfate Ion,Hydrogen Carbonate Ion,Strontium,Oxygen,Caesium,Barium,Chromium,Molybdenum,Manganese,Sodium Ion","[{'subject': 'Water chemical composition', 'subjectScheme': 'main'}, {'subject': 'Sudanian climate', 'subjectScheme': 'main'}, {'subject': 'pH', 'subjectScheme': 'var'}, {'subject': 'Nickel', 'subjectScheme': 'var'}, {'subject': 'Calcium Ion', 'subjectScheme': 'var'}, {'subject': 'Silicon', 'subjectScheme': 'var'}, {'subject': 'Vanadium', 'subjectScheme': 'var'}, {'subject': 'Boron', 'subjectScheme': 'var'}, {'subject': 'Magnesium Ion', 'subjectScheme': 'var'}, {'subject': 'Water Temperature', 'subjectScheme': 'var'}, {'subject': 'Lead', 'subjectScheme': 'var'}, {'subject': 'Arsenic', 'subjectScheme': 'var'}, {'subject': 'delta Oxygen-18', 'subjectScheme': 'var'}, {'subject': 'Conductivity', 'subjectScheme': 'var'}, {'subject': 'Uranium', 'subjectScheme': 'var'}, {'subject': 'Aluminium', 'subjectScheme': 'var'}, {'subject': 'Chloride Ion', 'subjectScheme': 'var'}, {'subject': 'Nitrate Ion', 'subjectScheme': 'var'}, {'subject': 'Cobalt', 'subjectScheme': 'var'}, {'subject': 'Zinc', 'subjectScheme': 'var'}, {'subject': 'delta Deuterium', 'subjectScheme': 'var'}, {'subject': 'Potassium Ion', 'subjectScheme': 'var'}, {'subject': 'Copper', 'subjectScheme': 'var'}, {'subject': 'Rubidium', 'subjectScheme': 'var'}, {'subject': 'Lithium', 'subjectScheme': 'var'}, {'subject': 'Sulfate Ion', 'subjectScheme': 'var'}, {'subject': 'Hydrogen Carbonate Ion', 'subjectScheme': 'var'}, {'subject': 'Strontium', 'subjectScheme': 'var'}, {'subject': 'Oxygen', 'subjectScheme': 'var'}, {'subject': 'Caesium', 'subjectScheme': 'var'}, {'subject': 'Barium', 'subjectScheme': 'var'}, {'subject': 'Chromium', 'subjectScheme': 'var'}, {'subject': 'Molybdenum', 'subjectScheme': 'var'}, {'subject': 'Manganese', 'subjectScheme': 'var'}, {'subject': 'Sodium Ion', 'subjectScheme': 'var'}]",,"['CSV', 'NETCDF', 'O&M 1.0']",,,"['Cites', 'IsPartOf', 'IsPartOf']",
10.6084/m9.figshare.16786741,Additional file 13 of Open-label randomized controlled trial of ultra-low tidal ventilation without extracorporeal circulation in patients with COVID-19 pneumonia and moderate to severe ARDS: study protocol for the VT4COVID trial,figshare,2021,,Text,Creative Commons Attribution 4.0 International,Additional file 13. Ethical approval document (English).,mds,True,findable,0,0,16,1,0,2021-10-12T03:41:44.000Z,2021-10-12T03:41:47.000Z,figshare.ars,otjm,"Medicine,Cell Biology,Physiology,FOS: Biological sciences,Biotechnology,Cancer,Mental Health,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': 'Biotechnology'}, {'subject': 'Cancer'}, {'subject': 'Mental Health'}, {'subject': 'Computational Biology'}]",['18100 Bytes'],,,,"['IsIdenticalTo', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'IsSupplementTo']","[['IsIdenticalTo', '10.6084/m9.figshare.16786741']]"
10.57745/7rfnnp,"Replication data for the publication ""Knowledge coproduction to improve assessments of nature’s contributions to people""",Recherche Data Gouv,2023,,Dataset,,"This repository contains the auxiliary data to reproduce the results of the publication: Vallet et al., ""Knowledge coproduction to improve assessments of nature’s contributions to people"" (https://doi.org/10.1111/cobi.14182). The code can be found here: https://gitlab.dsi.universite-paris-saclay.fr/agata/medicinal_plants/medicinal_plants_coproduction. Please see the README document for a description of the files.",mds,True,findable,130,13,0,0,0,2023-08-03T16:13:00.000Z,2023-10-26T14:20:08.000Z,rdg.prod,rdg,,,,,,,"['HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart', 'HasPart']",
10.26302/sshade/bandlist_raman_kutnohorite,Raman bandlist of natural Kutnohorite,SSHADE/BANDLIST (OSUG Data Center),2023,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,0,0,0,0,0,2023-09-02T14:28:51.000Z,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'],,,"['IsPartOf', 'IsPartOf', 'IsDerivedFrom', 'Cites', 'IsSourceOf', 'Cites', 'IsSourceOf', 'Cites', 'IsDerivedFrom', 'Cites', 'IsSourceOf', 'Cites', 'IsSourceOf', 'Cites', 'IsDerivedFrom', 'Cites']",
10.5281/zenodo.5243355,Swedish DBnary archive in original Lemon format,Zenodo,2021,sv,Dataset,"Creative Commons Attribution Share Alike 4.0 International,Open Access","The DBnary dataset is an extract of Wiktionary data from many language editions in RDF Format. Until July 1st 2017, the lexical data extracted from Wiktionary was modeled using the lemon vocabulary. This dataset contains the full archive of all DBnary dumps in Lemon format containing lexical information from Swedish language edition, ranging from 7th April 2015 to 1st July 2017. After July 2017, DBnary data has been modeled using the ontolex model and will be available in another Zenodo entry.",mds,True,findable,0,0,0,0,0,2021-08-24T11:50:12.000Z,2021-08-24T11:50:13.000Z,cern.zenodo,cern,"Wiktionary,Lemon,Lexical Data,RDF","[{'subject': 'Wiktionary'}, {'subject': 'Lemon'}, {'subject': 'Lexical Data'}, {'subject': 'RDF'}]",,,,,"['IsDocumentedBy', 'HasVersion', 'IsPartOf']","[['IsVersionOf', '10.5281/zenodo.5243355']]"
10.5281/zenodo.10951600,Response to Sea Surface Temperature and Primary Productivity to change in Earth's Orbit Eccentricity - Simulations,Zenodo,2024,,Dataset,Creative Commons Attribution 4.0 International,"This dataset contains ocean and ocean biogeochemistry outputs from modeling experiments with present-day geography and various Earth's orbit confiurations. The set of simulation targets the role of Eccentricity on the tropical ocean sea surface temperature and primary productivity (Beaufort & Sarr, 2024) . The simulations have been run using the IPSL-CM5A2 General Circulation Model (Sepulchre et al. 2020 - IPSL-CM5A2 – an Earth system model designed formulti-millennial climate simulations, GMD) and offline version of PISCESv2 model (Aumont et al., 2015 - PISCES-v2: an ocean biogeochemical model for carbon and ecosystem studies, GMD). It includes 4 simulations. Data are monthly averages over the last 100 years of the simulations.
Complementary outputs (4 simulations) can be found at https://www.seanoe.org/data/00728/84031/ (Beaufort et al., 2022)",api,True,findable,0,0,0,0,1,2024-04-11T20:07:00.000Z,2024-04-11T20:07:01.000Z,cern.zenodo,cern,Paleoclimatology,"[{'subject': 'Paleoclimatology', 'subjectScheme': 'EuroSciVoc'}]",,,,,"['Continues', 'IsPublishedIn', 'HasVersion']",
10.6084/m9.figshare.21430971,Additional file 1 of Digitally-supported patient-centered asynchronous outpatient follow-up in rheumatoid arthritis - an explorative qualitative study,figshare,2022,,Text,Creative Commons Attribution 4.0 International,Supplementary Material 1,mds,True,findable,0,0,0,0,0,2022-10-29T03:17:13.000Z,2022-10-29T03:17:13.000Z,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)'}]",['24235 Bytes'],,,,"['IsSupplementTo', 'IsIdenticalTo']","[['IsIdenticalTo', '10.6084/m9.figshare.21430971']]"
10.6084/m9.figshare.22620034,"Additional file 2 of Biallelic variants in NOS3 and GUCY1A3, the two major genes of the nitric oxide pathway, cause moyamoya cerebral angiopathy",figshare,2023,,Text,Creative Commons Attribution 4.0 International,Additional file 2: 3D structural analysis of the functional consequences of the eNOS p.C648R variant and sGC alpha1 subunit p.R593H variant.,mds,True,findable,0,0,0,0,0,2023-04-13T14:39:41.000Z,2023-04-13T16:07:53.000Z,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)'}]",['36825 Bytes'],,,,['IsSupplementTo'],
10.5281/zenodo.4014725,Supplement to : Accelerated Snow Melt in the Russian Caucasus Mountains After the Saharan Dust Outbreak in March 2018,Zenodo,2020,,Dataset,"Creative Commons Attribution 4.0 International,Open Access","These datasets contains all the data used in Accelerated Snow Melt in the Russian Caucasus Mountains After the Saharan Dust Outbreak in March 2018 by Dumont et al., in Journal of Geophysical Research.<br> This dataset includes : Sentinel-2 cloud masks, snow depth measurements, snow surface impurity content estimated from Sentinel-2, Sentinel-2 surface reflectances and digital elevation models. Dumont, M., Tuzet, F., Gascoin, S., Picard, G., Kutuzov, S., Lafaysse, M., et al. (2020). Accelerated snow melt in the Russian Caucasus mountains after the Saharan dust outbreak in March 2018. Journal of Geophysical Research: Earth Surface, 125, e2020JF005641. https://doi.org/10.1029/2020JF005641",mds,True,findable,0,0,0,0,0,2020-09-04T09:24:13.000Z,2020-09-04T09:24:14.000Z,cern.zenodo,cern,"snow,light absorbing impurities,remote sensing","[{'subject': 'snow'}, {'subject': 'light absorbing impurities'}, {'subject': 'remote sensing'}]",,,,,['HasVersion'],"[['IsVersionOf', '10.5281/zenodo.4014725']]"
10.5281/zenodo.7064040,"Figure data sets for the paper ""Coherent optical-microwave interface for manipulation of low-field electronic clock transitions in 171Yb3+:Y2SiO5""",Zenodo,2022,,Dataset,"Creative Commons Attribution 4.0 International,Open Access",Figure data sets.,mds,True,findable,0,0,0,0,0,2022-09-09T08:55:06.000Z,2022-09-09T08:55:06.000Z,cern.zenodo,cern,,,,,,,['HasVersion'],"[['IsVersionOf', '10.5281/zenodo.7064040']]"
10.5281/zenodo.4639768,Upslope migration of snow avalanches in a warming climate: data and model source files,Zenodo,2021,en,Dataset,"Creative Commons Attribution 4.0 International,Open Access","Complete data and model source files corresponding to: Giacona, F., Eckert, N., Corona, C., Mainieri, R., Morin, S., Stoffel, M., Martin, B., Naaim, M. (2021). Upslope migration of snow avalanches in a warming climate. Proceedings of the National Academy of Sciences America, Nov 2021, 118 (44) e2107306118; DOI: 10.1073/pnas.2107306118",mds,True,findable,0,0,0,0,0,2021-09-21T09:49:24.000Z,2021-09-21T09:49:25.000Z,cern.zenodo,cern,"Natural Hazards,Cryosphere,Climate change,Historical Data,Hierarchical Bayesian Modelling","[{'subject': 'Natural Hazards'}, {'subject': 'Cryosphere'}, {'subject': 'Climate change'}, {'subject': 'Historical Data'}, {'subject': 'Hierarchical Bayesian Modelling'}]",,,,,['HasVersion'],"[['IsVersionOf', '10.5281/zenodo.4639768']]"
10.5061/dryad.b8gtht78h,Global gradients in intraspecific variation in vegetative and floral traits are partially associated with climate and species richness,Dryad,2020,en,Dataset,Creative Commons Zero v1.0 Universal,"Aim Intraspecific trait variation (ITV) within natural plant communities
can be large, influencing local ecological processes and dynamics. Here,
we shed light on how ITV in vegetative and floral traits responds to
large-scale abiotic and biotic gradients (i.e. climate and species
richness). Specifically, we tested if associations of ITV with
temperature, precipitation and species richness were consistent with any
of from four hypotheses relating to stress-tolerance and competition.
Furthermore, we estimated the degree of correlation between ITV in
vegetative and floral traits and how they vary along the gradients.
Location Global. Time period 1975-2016. Major taxa studied Herbaceous and
woody plants. Methods We compiled a dataset of 18,112 measurements of the
absolute extent of ITV (measured as coefficient of variation) in nine
vegetative and seven floral traits from 2,774 herbaceous and woody species
at 2,306 locations. Results Large-scale associations between ITV and
climate were trait-specific and more prominent for vegetative traits,
especially leaf morphology, than for floral traits. ITV showed pronounced
associations with climate, with lower ITV values in colder areas and
higher values in drier areas. The associations of ITV with species
richness were inconsistent across traits. Species-specific associations
across gradients were often idiosyncratic and covariation in ITV was
weaker between vegetative and floral traits than within the two trait
groups. Main conclusions Our results show that, depending on the traits
considered, ITV either increased or decreased with climate stress and
species richness, suggesting that both factors can constrain or enhance
ITV, which might foster plant-population persistence under stressful
conditions. Given the species-specific responses and covariation in ITV,
associations can be hard to predict for traits and species not yet
studied. We conclude that considering ITV can improve our understanding of
how plants cope with stressful conditions and environmental change across
spatial and biological scales.",mds,True,findable,263,48,1,1,0,2020-02-04T15:41:47.000Z,2020-02-04T15:41:48.000Z,dryad.dryad,dryad,"functional plant traits,flower trait,Leaf trait","[{'subject': 'functional plant traits'}, {'subject': 'flower trait'}, {'subject': 'Leaf trait'}]",['2610890 bytes'],,,,['IsCitedBy'],
10.5281/zenodo.7141345,Crocus snowpack simulations across southwestern Canada and northwestern US,Zenodo,2022,,Dataset,"Open Government Licence - Canada,Open Access","The simulated snowpack properties (snow water equivalent, snow depth) were obtained from the detailed snowpack model Crocus (Vionnet et al., 2012; Lafaysse et al., 2017), implemented in the SVS land surface scheme version 2 (Soil Vegetation and Snow; Garnaud et al., 2019). Snowpack simulations were carried out from 1 September 2019 to 30 June 2020 over a grid covering southwestern Canada and northwestern US at 2.5-km grid spacing. The simulations were driven by short-meteorological forecast from the High-Resolution Deterministic Prediction System (HRDPS; Milbrandt et al., 2016) combined with precipitation estimates from the Canadian Precipitation Analysis (Fortin et al., 2018). Four precipitation-phase partitioning methods (PPMs) were used to derive the liquid and solid precipitation rates from the total precipitation available in the atmospheric forcing. More details about the simulations are and the PPMS given in the readme file included in the dataset. This dataset has been used in a study submitted to Water Resources Research (Vionnet et al, 2022). <strong>References: </strong> Fortin, V., Roy, G., Stadnyk, T., Koenig, K., Gasset, N., & Mahidjiba, A. (2018). Ten years of science based on the Canadian precipitation analysis: A CaPA system overview and literature review. <em>Atmosphere-Ocean</em>, <em>56</em>(3), 178-196. Garnaud, C., Bélair, S., Carrera, M. L., Derksen, C., Bilodeau, B., Abrahamowicz, M., ... & Vionnet, V. (2019). Quantifying snow mass mission concept trade-offs using an observing system simulation experiment. <em>Journal of Hydrometeorology</em>, <em>20</em>(1), 155-173. Milbrandt, J. A., Bélair, S., Faucher, M., Vallée, M., Carrera, M. L., & Glazer, A. (2016). The pan-Canadian high resolution (2.5 km) deterministic prediction system. <em>Weather and Forecasting</em>, <em>31</em>(6), 1791-1816. Lafaysse, M., Cluzet, B., Dumont, M., Lejeune, Y., Vionnet, V., & Morin, S. (2017). A multiphysical ensemble system of numerical snow modelling. <em>The Cryosphere</em>, <em>11</em>(3), 1173-1198. Vionnet, V., Brun, E., Morin, S., Boone, A., Faroux, S., Le Moigne, P., ... & Willemet, J. M. (2012). The detailed snowpack scheme Crocus and its implementation in SURFEX v7. 2. <em>Geoscientific Model Development</em>, <em>5</em>(3), 773-791. Vionnet, V., Verville, M., Fortin, V., Brugman, M., Abrahamowicz, M., Lemay, F., Thériault, J.M., Lafaysse M., and Milbrandt, J.A. : Snow level from post-processing of atmospheric model improves snowfall estimates and snowpack predictions in mountains, <em>Water Resources Research</em>, 2022, Accepted with minor revisions",mds,True,findable,0,0,0,0,0,2022-10-05T15:38:21.000Z,2022-10-05T15:38:22.000Z,cern.zenodo,cern,"snow,precipitation phase,mountains","[{'subject': 'snow'}, {'subject': 'precipitation phase'}, {'subject': 'mountains'}]",,,,,['HasVersion'],"[['IsVersionOf', '10.5281/zenodo.7141345']]"
10.5061/dryad.93n5r,Data from: Decomposing changes in phylogenetic and functional diversity over space and time,Dryad,2015,en,Dataset,Creative Commons Zero v1.0 Universal,"1. The α, β, γ diversity decomposition methodology is commonly used to
investigate changes in diversity over space or time but rarely conjointly.
However, with the ever-increasing availability of large-scale biodiversity
monitoring data, there is a need for a sound methodology capable of
simultaneously accounting for spatial and temporal changes in diversity.
2. Using the properties of Chao's index, we adapted Rao's
framework of diversity decomposition between orthogonal dimensions to a
multiplicative α, β, γ decomposition of functional or phylogenetic
diversity over space and time, thereby combining their respective
properties. We also developed guidelines for interpreting both temporal
and spatial β-diversities and their interaction. 3. We characterised the
range of β-diversity estimates and their relationship to the nested
decomposition of diversity. Using simulations, we empirically demonstrated
that temporal and spatial β-diversities are independent from each other
and from α and γ-diversities when the study design is balanced, but not
otherwise. Furthermore, we showed that the interaction term between the
temporal and the spatial β-diversities lacked such properties. 4. We
illustrated our methodology with a case study of the spatio-temporal
dynamics of functional diversity in bird assemblages in four regions of
France. Based on these data, our method makes it possible to discriminate
between regions experiencing different diversity changes in time. Our
methodology may therefore be valuable for comparing diversity changes over
space and time using large-scale datasets of repeated surveys.",mds,True,findable,301,24,1,1,0,2014-10-17T15:27:54.000Z,2014-10-17T15:27:56.000Z,dryad.dryad,dryad,"Apus pallidus,Luscinia svecica,Merops apiaster,Falco subbuteo,Sterna sandvicensis,Passer montanus,Lanius excubator subsp. meridionalis,Lanius excubitor,Lagopus mutus,Charadrius alexandrinus,Cinclus cinclus,Phylloscopus trochilus,Sturnus unicolor,Scolopax rusticola,Streptopelia turtur,Emberiza hortulana,Acrocephalus arundinaceus,Carduelis cannabina,Hirundo daurica,Buteo buteo,Ardea purpurea,Asio otus,Circaetus gallicus,Netta rufina,Milvus milvus,Parus cristatus,Jynx torquilla,Parus ater,Circus aeruginosus,Lanius senator,Acrocephalus schoenobaenus,Larus melanocephalus,Athene noctua,Dryocopus martius,Miliaria calandra,Lanius collurio,Sylvia hortensis,Cygnus olor,Erithacus rubecula,Corvus corax,Picus canus,Tyto alba,Phoenicopterus ruber,Pyrrhula pyrrhula,Motacilla flava,Prunella collaris,Delichon urbica,Luscinia megarhynchos,Haematopus ostralegus,Regulus ignicapillus,Larus ridibundus,Alectoris graeca,Anas querquedula,Tringa totanus,Perdix perdix,Turdus philomelos,Accipiter nisus,Phoenicurus phoenicurus,Sitta europaea,Cisticola juncidis,Troglodytes troglodytes,Carduelis spinus,Emberiza citrinella,Turdus merula,Anthus pratensis,Larus argentatus,Streptopelia decaocto,Nucifraga caryocatactes,Panurus biarmicus,Corvus frugilegus,Fringilla coelebs,Alauda arvensis,Phoenicurus ochruros,Aythya ferina,Clamator glandarius,Carduelis carduelis,Loxia curvirostra,Bonasa bonasia,Himantopus himantopus,Hippolais icterina,Pyrrhocorax pyrrhocorax,Prunella modularis,Carduelis flammea,Apus melba,Bubulcus ibis,Alcedo atthis,Parus major,Alectoris rufa,Dendrocopos minor,Sylvia conspicillata,Vanellus vanellus,Monticola solitarius,Accipiter gentilis,Dendrocopos major,Calandrella brachydactyla,Emberiza cia,Saxicola rubetra,Falco peregrinus,Garrulus glandarius,Columba palumbus,Picus viridis,Ardea cinerea,Aythya fuligula,Burhinus oedicnemus,Crex Crex,Podiceps cristatus,Riparia riparia,Oenanthe hispanica,Anthus spinoletta,Bubo bubo,Locustella luscinioides,Pyrrhocorax graculus,Cuculus canorus,Acrocephalus palustris,Chlidonias hybridus,Anthus campestris,Cettia cetti,Larus marinus,Milvus migrans,Anthus trivialis,Pica pica,Strix aluco,Tetrax tetrax,Upupa epops,Fulica atra,Gallinago gallinago,Passer domesticus,Porzana porzana,Coracias garrulus,Sylvia borin,Phylloscopus bonelli,Sylvia curruca,Acrocephalus scirpaceus,Hippolais polyglotta,Lullula arborea,Galerida cristata,Certhia brachydactyla,Certhia familiaris,Otus scops,Anser anser,Circus pygargus,Motacilla cinerea,Serinus serinus,Gyps fulvus,Saxicola torquata,Emberiza schoeniclus,Locustella naevia,Motacilla alba,Recurvirostra avosetta,Sylvia communis,Apus apus,Circus cyaneus,Casmerodius albus,Hirundo rustica,Phalacrocorax carbo,Gallinula chloropus,Ardeola ralloides,Coturnix coturnix,Larus graellsii,Limosa limosa,Platalea leucorodia,Sturnus vulgaris,communities,Turdus viscivorus,Parus palustris,Egretta garzetta,Oriolus oriolus,Rallus aquaticus,Sylvia atricapilla,Muscicapa striata,Phasianus colchicus,Anas crecca,Parus montanus,Turdus torquatus,Sylvia cantillans,Corvus monedula,Aegithalos caudatus,Botaurus stellaris,Ixobrychus minutus,Serinus citrinella,Petronia petronia,Regulus regulus,Corvus cornix,Falco naumanni,Numenius arquata,Columba oenas,Nycticorax nycticorax,Gelochelidon nilotica,Hieraaetus pennatus,Phylloscopus sibilatrix,Ptyonoprogne rupestris,Oenanthe oenanthe,Sterna albifrons,Ciconia ciconia,Ficedula hypoleuca,Phylloscopus collybita,Sylvia melanocephala,Monticola saxatilis,Coccothraustes coccothraustes,Tachybaptus ruficollis,Falco tinnunculus,Melanocorypha calandra,Dendrocopos medius,Pandion haliaetus,Tadorna tadorna,Columba livia,Pernis apivorus,Turdus pilaris,Sylvia undata,Caprimulgus europaeus,Charadrius dubius,Parus caeruleus,Anas platyrhynchos,Tichodroma muraria,Chloris chloris,Emberiza cirlus,Sterna hirundo","[{'subject': 'Apus pallidus'}, {'subject': 'Luscinia svecica'}, {'subject': 'Merops apiaster'}, {'subject': 'Falco subbuteo'}, {'subject': 'Sterna sandvicensis'}, {'subject': 'Passer montanus'}, {'subject': 'Lanius excubator subsp. meridionalis'}, {'subject': 'Lanius excubitor'}, {'subject': 'Lagopus mutus'}, {'subject': 'Charadrius alexandrinus'}, {'subject': 'Cinclus cinclus'}, {'subject': 'Phylloscopus trochilus'}, {'subject': 'Sturnus unicolor'}, {'subject': 'Scolopax rusticola'}, {'subject': 'Streptopelia turtur'}, {'subject': 'Emberiza hortulana'}, {'subject': 'Acrocephalus arundinaceus'}, {'subject': 'Carduelis cannabina'}, {'subject': 'Hirundo daurica'}, {'subject': 'Buteo buteo'}, {'subject': 'Ardea purpurea'}, {'subject': 'Asio otus'}, {'subject': 'Circaetus gallicus'}, {'subject': 'Netta rufina'}, {'subject': 'Milvus milvus'}, {'subject': 'Parus cristatus'}, {'subject': 'Jynx torquilla'}, {'subject': 'Parus ater'}, {'subject': 'Circus aeruginosus'}, {'subject': 'Lanius senator'}, {'subject': 'Acrocephalus schoenobaenus'}, {'subject': 'Larus melanocephalus'}, {'subject': 'Athene noctua'}, {'subject': 'Dryocopus martius'}, {'subject': 'Miliaria calandra'}, {'subject': 'Lanius collurio'}, {'subject': 'Sylvia hortensis'}, {'subject': 'Cygnus olor'}, {'subject': 'Erithacus rubecula'}, {'subject': 'Corvus corax'}, {'subject': 'Picus canus'}, {'subject': 'Tyto alba'}, {'subject': 'Phoenicopterus ruber'}, {'subject': 'Pyrrhula pyrrhula'}, {'subject': 'Motacilla flava'}, {'subject': 'Prunella collaris'}, {'subject': 'Delichon urbica'}, {'subject': 'Luscinia megarhynchos'}, {'subject': 'Haematopus ostralegus'}, {'subject': 'Regulus ignicapillus'}, {'subject': 'Larus ridibundus'}, {'subject': 'Alectoris graeca'}, {'subject': 'Anas querquedula'}, {'subject': 'Tringa totanus'}, {'subject': 'Perdix perdix'}, {'subject': 'Turdus philomelos'}, {'subject': 'Accipiter nisus'}, {'subject': 'Phoenicurus phoenicurus'}, {'subject': 'Sitta europaea'}, {'subject': 'Cisticola juncidis'}, {'subject': 'Troglodytes troglodytes'}, {'subject': 'Carduelis spinus'}, {'subject': 'Emberiza citrinella'}, {'subject': 'Turdus merula'}, {'subject': 'Anthus pratensis'}, {'subject': 'Larus argentatus'}, {'subject': 'Streptopelia decaocto'}, {'subject': 'Nucifraga caryocatactes'}, {'subject': 'Panurus biarmicus'}, {'subject': 'Corvus frugilegus'}, {'subject': 'Fringilla coelebs'}, {'subject': 'Alauda arvensis'}, {'subject': 'Phoenicurus ochruros'}, {'subject': 'Aythya ferina'}, {'subject': 'Clamator glandarius'}, {'subject': 'Carduelis carduelis'}, {'subject': 'Loxia curvirostra'}, {'subject': 'Bonasa bonasia'}, {'subject': 'Himantopus himantopus'}, {'subject': 'Hippolais icterina'}, {'subject': 'Pyrrhocorax pyrrhocorax'}, {'subject': 'Prunella modularis'}, {'subject': 'Carduelis flammea'}, {'subject': 'Apus melba'}, {'subject': 'Bubulcus ibis'}, {'subject': 'Alcedo atthis'}, {'subject': 'Parus major'}, {'subject': 'Alectoris rufa'}, {'subject': 'Dendrocopos minor'}, {'subject': 'Sylvia conspicillata'}, {'subject': 'Vanellus vanellus'}, {'subject': 'Monticola solitarius'}, {'subject': 'Accipiter gentilis'}, {'subject': 'Dendrocopos major'}, {'subject': 'Calandrella brachydactyla'}, {'subject': 'Emberiza cia'}, {'subject': 'Saxicola rubetra'}, {'subject': 'Falco peregrinus'}, {'subject': 'Garrulus glandarius'}, {'subject': 'Columba palumbus'}, {'subject': 'Picus viridis'}, {'subject': 'Ardea cinerea'}, {'subject': 'Aythya fuligula'}, {'subject': 'Burhinus oedicnemus'}, {'subject': 'Crex Crex'}, {'subject': 'Podiceps cristatus'}, {'subject': 'Riparia riparia'}, {'subject': 'Oenanthe hispanica'}, {'subject': 'Anthus spinoletta'}, {'subject': 'Bubo bubo'}, {'subject': 'Locustella luscinioides'}, {'subject': 'Pyrrhocorax graculus'}, {'subject': 'Cuculus canorus'}, {'subject': 'Acrocephalus palustris'}, {'subject': 'Chlidonias hybridus'}, {'subject': 'Anthus campestris'}, {'subject': 'Cettia cetti'}, {'subject': 'Larus marinus'}, {'subject': 'Milvus migrans'}, {'subject': 'Anthus trivialis'}, {'subject': 'Pica pica'}, {'subject': 'Strix aluco'}, {'subject': 'Tetrax tetrax'}, {'subject': 'Upupa epops'}, {'subject': 'Fulica atra'}, {'subject': 'Gallinago gallinago'}, {'subject': 'Passer domesticus'}, {'subject': 'Porzana porzana'}, {'subject': 'Coracias garrulus'}, {'subject': 'Sylvia borin'}, {'subject': 'Phylloscopus bonelli'}, {'subject': 'Sylvia curruca'}, {'subject': 'Acrocephalus scirpaceus'}, {'subject': 'Hippolais polyglotta'}, {'subject': 'Lullula arborea'}, {'subject': 'Galerida cristata'}, {'subject': 'Certhia brachydactyla'}, {'subject': 'Certhia familiaris'}, {'subject': 'Otus scops'}, {'subject': 'Anser anser'}, {'subject': 'Circus pygargus'}, {'subject': 'Motacilla cinerea'}, {'subject': 'Serinus serinus'}, {'subject': 'Gyps fulvus'}, {'subject': 'Saxicola torquata'}, {'subject': 'Emberiza schoeniclus'}, {'subject': 'Locustella naevia'}, {'subject': 'Motacilla alba'}, {'subject': 'Recurvirostra avosetta'}, {'subject': 'Sylvia communis'}, {'subject': 'Apus apus'}, {'subject': 'Circus cyaneus'}, {'subject': 'Casmerodius albus'}, {'subject': 'Hirundo rustica'}, {'subject': 'Phalacrocorax carbo'}, {'subject': 'Gallinula chloropus'}, {'subject': 'Ardeola ralloides'}, {'subject': 'Coturnix coturnix'}, {'subject': 'Larus graellsii'}, {'subject': 'Limosa limosa'}, {'subject': 'Platalea leucorodia'}, {'subject': 'Sturnus vulgaris'}, {'subject': 'communities'}, {'subject': 'Turdus viscivorus'}, {'subject': 'Parus palustris'}, {'subject': 'Egretta garzetta'}, {'subject': 'Oriolus oriolus'}, {'subject': 'Rallus aquaticus'}, {'subject': 'Sylvia atricapilla'}, {'subject': 'Muscicapa striata'}, {'subject': 'Phasianus colchicus'}, {'subject': 'Anas crecca'}, {'subject': 'Parus montanus'}, {'subject': 'Turdus torquatus'}, {'subject': 'Sylvia cantillans'}, {'subject': 'Corvus monedula'}, {'subject': 'Aegithalos caudatus'}, {'subject': 'Botaurus stellaris'}, {'subject': 'Ixobrychus minutus'}, {'subject': 'Serinus citrinella'}, {'subject': 'Petronia petronia'}, {'subject': 'Regulus regulus'}, {'subject': 'Corvus cornix'}, {'subject': 'Falco naumanni'}, {'subject': 'Numenius arquata'}, {'subject': 'Columba oenas'}, {'subject': 'Nycticorax nycticorax'}, {'subject': 'Gelochelidon nilotica'}, {'subject': 'Hieraaetus pennatus'}, {'subject': 'Phylloscopus sibilatrix'}, {'subject': 'Ptyonoprogne rupestris'}, {'subject': 'Oenanthe oenanthe'}, {'subject': 'Sterna albifrons'}, {'subject': 'Ciconia ciconia'}, {'subject': 'Ficedula hypoleuca'}, {'subject': 'Phylloscopus collybita'}, {'subject': 'Sylvia melanocephala'}, {'subject': 'Monticola saxatilis'}, {'subject': 'Coccothraustes coccothraustes'}, {'subject': 'Tachybaptus ruficollis'}, {'subject': 'Falco tinnunculus'}, {'subject': 'Melanocorypha calandra'}, {'subject': 'Dendrocopos medius'}, {'subject': 'Pandion haliaetus'}, {'subject': 'Tadorna tadorna'}, {'subject': 'Columba livia'}, {'subject': 'Pernis apivorus'}, {'subject': 'Turdus pilaris'}, {'subject': 'Sylvia undata'}, {'subject': 'Caprimulgus europaeus'}, {'subject': 'Charadrius dubius'}, {'subject': 'Parus caeruleus'}, {'subject': 'Anas platyrhynchos'}, {'subject': 'Tichodroma muraria'}, {'subject': 'Chloris chloris'}, {'subject': 'Emberiza cirlus'}, {'subject': 'Sterna hirundo'}]",['123652 bytes'],,,,['IsCitedBy'],
10.15778/resif.zl2019,Dense nodal seismic array temporary experiment on the banks of the Sévraisse River in Alpes (RESIF-SISMOB),RESIF - Réseau Sismologique et géodésique Français,2022,,Dataset,,This experiment consists in continuous seismic records acquired during an entire summer season (early June-early October) at 40 stations along the banks of the Sévraisse River (French Alps). The seismic array consists in sub arrays of 5 sensors designed to enable sub-wavelength analysis while covering a representative part of the river braided reach. Our ultimate goal is to locate river seismic sources generated by sediment transport and/or fluid flow as well as to evaluate their spatial and temporal changes over various scales.,mds,True,findable,0,0,0,0,0,2021-12-06T15:36:24.000Z,2021-12-06T15:38:20.000Z,inist.resif,vcob,"River,Seismic,Morphology,Interferometry,Localisation,Bedload","[{'subject': 'River'}, {'subject': 'Seismic'}, {'subject': 'Morphology'}, {'subject': 'Interferometry'}, {'subject': 'Localisation'}, {'subject': 'Bedload'}]","['40 stations, 590Go (miniseed format)']","['Miniseed data', 'hdf5 data', 'stationXML metadata']",,,['IsCitedBy'],
10.6084/m9.figshare.20221982,Additional file 5 of Response to PEEP in COVID-19 ARDS patients with and without extracorporeal membrane oxygenation. A multicenter case–control computed tomography study,figshare,2022,,Text,Creative Commons Attribution 4.0 International,Additional file 5: Univariate analysis of variables associated with lung recruitment,mds,True,findable,0,0,27,1,0,2022-07-04T06:41:13.000Z,2022-07-04T06:41:14.000Z,figshare.ars,otjm,"Medicine,Microbiology,FOS: Biological sciences,Cell Biology,Physiology,Immunology,FOS: Clinical medicine,Science Policy","[{'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': 'Cell Biology'}, {'subject': 'Physiology'}, {'subject': 'Immunology'}, {'subject': 'FOS: Clinical medicine', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': 'Science Policy'}]",['19706 Bytes'],,,,"['References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'IsSupplementTo']",
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,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,0,0,0,0,0,2021-09-07T06:39:19.000Z,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'],,,"['IsPartOf', 'IsPartOf']",
10.26302/sshade/experiment_ag_20130923_000,"Evolution with time of the MIR absorbance spectrum of Portlandite at -10, 0 and 10°C in contact with 2 bar CO2 gas",SSHADE/GhoSST (OSUG Data Center),2018,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.","Evolution with time of the MIR absorbance spectrum of Portlandite at -10, 0 and 10°C in contact with 2 bar CO2 gas",mds,True,findable,0,0,0,0,0,2019-12-28T15:02:50.000Z,2019-12-28T15:02:50.000Z,inist.sshade,mgeg,"commercial,oxide-hydroxide,Portlandite,carbonate,Calcite,Aragonite,physically adsorbed phase,Adsorbed water,inorganic molecular solid,H2O ice,laboratory measurement,transmission,microscopy,MIR,Mid-Infrared,absorbance","[{'subject': 'commercial'}, {'subject': 'oxide-hydroxide'}, {'subject': 'Portlandite'}, {'subject': 'carbonate'}, {'subject': 'Calcite'}, {'subject': 'Aragonite'}, {'subject': 'physically adsorbed phase'}, {'subject': 'Adsorbed water'}, {'subject': 'inorganic molecular solid'}, {'subject': 'H2O ice'}, {'subject': 'laboratory measurement'}, {'subject': 'transmission'}, {'subject': 'microscopy'}, {'subject': 'MIR'}, {'subject': 'Mid-Infrared'}, {'subject': 'absorbance'}]",['34 spectra'],['ASCII'],,,"['IsPartOf', 'IsPartOf', 'IsSourceOf']",
10.18150/damcb2,"Dataset from the analysis of dielectric, mechanical and calorimetric response of phosphonium ionic liquids with DCA, TCM and SCN anions",RepOD,2023,,Dataset,,"This dataset contains raw dielectric, mechanical and calorimetric data published in the article entitled “Self-Assembled Nanostructures in Aprotic Ionic Liquids Facilitate Charge Transport at Elevated Pressure” in ACS Applied Materials & Interfaces (https://pubs.acs.org/doi/10.1021/acsami.3c08606). The included data consists of results collected for three quaternary phosphonium ionic liquids with hydrophobic [P666,14 ] + cation and anions: thiocyanate [SCN] − , dicyanamide [DCA] − and tricyanomethanide [TCM] − . Raw data correspond to figures published in the main article and supporting information file.",mds,True,findable,0,0,0,0,0,2023-09-20T11:58:53.000Z,2023-09-20T12:01:51.000Z,tib.repod,repod,,,,,,,['IsPartOf'],
10.5281/zenodo.3952173,easystats/performance: performance 0.11.0,Zenodo,2024,,Software,Creative Commons Attribution 4.0 International,"New supported models
Rudimentary support for models of class serp from package serp.
New functions
simulate_residuals() and check_residuals(), to simulate and check residuals
from generalized linear (mixed) models. Simulating residuals is based on the
DHARMa package, and objects returned by simulate_residuals() inherit from
the DHARMa class, and thus can be used with any functions from the DHARMa
package. However, there are also implementations in the performance package,
such as check_overdispersion(), check_zeroinflation(), check_outliers()
or check_model().
Plots for check_model() have been improved. The Q-Q plots are now based
on simulated residuals from the DHARMa package for non-Gaussian models, thus
providing more accurate and informative plots. The half-normal QQ plot for
generalized linear models can still be obtained by setting the new argument
residual_type = ""normal"".
Following functions now support simulated residuals (from simulate_residuals())
resp. objects returned from DHARMa::simulateResiduals():
check_overdispersion()
check_zeroinflation()
check_outliers()
check_model()
General
Improved error messages for check_model() when QQ-plots cannot be created.
check_distribution() is more stable for possibly sparse data.
Bug fixes
Fixed issue in check_normality() for t-tests.
Fixed issue in check_itemscale() for data frame inputs, when factor_index
was not a named vector.",api,True,findable,0,0,0,1,0,2024-03-23T08:06:58.000Z,2024-03-23T08:06:58.000Z,cern.zenodo,cern,,,,,,,"['IsSupplementTo', 'HasVersion', 'HasVersion', 'HasVersion', 'HasVersion', 'HasVersion', 'HasVersion', 'HasVersion', 'HasVersion', 'HasVersion', 'HasVersion', 'HasVersion', 'HasVersion', 'HasVersion', 'HasVersion', 'HasVersion']","[['IsVersionOf', '10.5281/zenodo.3952173']]"
10.5281/zenodo.3628202,Terrestrial Laser Scanner observations of snow depth distribution at Col du Lautaret and Col du Lac Blanc mountain sites,Zenodo,2020,,Dataset,"Creative Commons Attribution 4.0 International,Open Access","This dataset contains snow depth distribution observations obtained in two high mountain experimental sites, Col du Lac Blanc and Col du Lautaret, both located in French Alps. The snow depth distribution maps were generated using a Terrestrial Laser Scanner (TLS) for 10 acquisition dates. Observations obtained in Col du Lac Blanc were acquired in the 2014-15 snow season while Col du Lautaret observations were acquired in 2017-18 snow season. The snow depth maps have a grid cell size of 1x1m. The two study sites have extensions comprised between 17 and 31 ha with elevations ranging from 2000-2100 m a.s.l. (Col du Lautaret)and 2600-2800 m a.s.l. (Col du Lac Blanc)and show a patchy distribution of bare soil and alpine grass. The dataset allows a better understanding of snow related processes in mountain areas.",mds,True,findable,0,0,0,0,0,2020-01-27T11:25:40.000Z,2020-01-27T11:25:41.000Z,cern.zenodo,cern,"snow depth distribution, mountain sites, terrestrial laser scanner observations","[{'subject': 'snow depth distribution, mountain sites, terrestrial laser scanner observations'}]",,,,,['HasVersion'],"[['IsVersionOf', '10.5281/zenodo.3628202']]"
10.17178/zaa_soil_temp.pne,Long term monitoring of near surface soil temperature in the Ecrins National Park,UGA – OSUG – PNE,2021,en,Dataset,"Creative Commons Attribution 4.0 International,For any publication using ZAA data, depending on the contribution of the data to the scientific results obtained, data users should either propose co-authorship to the data providers (doi Project leaders) or at least acknowledge their contribution.
The acknowledging sentence which should appear in publications using ZAA temp-soil data and products is in the readme file joint with the dataset","Monitoring of near-surface soil temperature in seasonaly snow-covered, mountain ecosystems located in the Ecrins National Park. Data are part of several research projects and monitoring programs examining the impact of climate change on snow cover dynamics, microclimate, species distribution and ecosystem functioning. Data include a GPS position, a date and time in UTC and a near-surface soil temperature (in °C) measured at 5 cm belowground using stand-alone temperature data logger.",mds,True,findable,0,0,0,0,0,2021-07-13T13:43:48.000Z,2021-07-13T13:43:50.000Z,inist.osug,jbru,"microclimate,mountain climate,long-term monitoring,soil,root zone,cold zone ecosystem,soil temperature","[{'subject': 'microclimate', 'subjectScheme': 'main'}, {'subject': 'mountain climate', 'subjectScheme': 'main'}, {'subject': 'long-term monitoring', 'subjectScheme': 'main'}, {'subject': 'soil', 'subjectScheme': 'main'}, {'subject': 'root zone', 'subjectScheme': 'main'}, {'subject': 'cold zone ecosystem', 'subjectScheme': 'main'}, {'subject': 'soil temperature', 'subjectScheme': 'var'}]",,['CSV'],,,"['Cites', 'IsPartOf']",
10.6084/m9.figshare.c.5999772,Impact of prolonged requirement for insulin on 90-day mortality in critically ill patients without previous diabetic treatments: a post hoc analysis of the CONTROLING randomized control trial,figshare,2022,,Collection,Creative Commons Attribution 4.0 International,"Abstract Background Stress hyperglycemia can persist during an intensive care unit (ICU) stay and result in prolonged requirement for insulin (PRI). The impact of PRI on ICU patient outcomes is not known. We evaluated the relationship between PRI and Day 90 mortality in ICU patients without previous diabetic treatments. Methods This is a post hoc analysis of the CONTROLING trial, involving 12 French ICUs. Patients in the personalized glucose control arm with an ICU length of stay ≥ 5 days and who had never previously received diabetic treatments (oral drugs or insulin) were included. Personalized blood glucose targets were estimated on their preadmission usual glycemia as estimated by their glycated A1c hemoglobin (HbA1C). PRI was defined by insulin requirement. The relationship between PRI on Day 5 and 90-day mortality was assessed by Cox survival models with inverse probability of treatment weighting (IPTW). Glycemic control was defined as at least one blood glucose value below the blood glucose target value on Day 5. Results A total of 476 patients were included, of whom 62.4% were male, with a median age of 66 (54–76) years. Median values for SAPS II and HbA1C were 50 (37.5–64) and 5.7 (5.4–6.1)%, respectively. PRI was observed in 364/476 (72.5%) patients on Day 5. 90-day mortality was 23.1% in the whole cohort, 25.3% in the PRI group and 16.1% in the non-PRI group (p < 0.01). IPTW analysis showed that PRI on Day 5 was not associated with Day 90 mortality (IPTWHR = 1.22; CI 95% 0.84–1.75; p = 0.29), whereas PRI without glycemic control was associated with an increased risk of death at Day 90 (IPTWHR = 3.34; CI 95% 1.26–8.83; p < 0.01). Conclusion In ICU patients without previous diabetic treatments, only PRI without glycemic control on Day 5 was associated with an increased risk of death. Additional studies are required to determine the factors contributing to these results.",mds,True,findable,0,0,0,0,0,2022-05-17T06:14:08.000Z,2022-05-17T06:14:09.000Z,figshare.ars,otjm,"Medicine,Cell Biology,Genetics,FOS: Biological sciences,Physiology,Pharmacology,Biotechnology,Chemical Sciences not elsewhere classified,Infectious Diseases,FOS: Health sciences,Virology","[{'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': 'Physiology'}, {'subject': 'Pharmacology'}, {'subject': 'Biotechnology'}, {'subject': 'Chemical Sciences not elsewhere classified'}, {'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'}]",,,,,['IsIdenticalTo'],"[['IsIdenticalTo', '10.6084/m9.figshare.c.5999772']]"
10.5281/zenodo.10020956,robertxa/Therion-TextWrangler: First Release,Zenodo,2023,,Software,Creative Commons Attribution 4.0 International,Syntax Color file of Therion input files with TexWrangler,api,True,findable,0,0,0,0,0,2023-10-19T08:40:29.000Z,2023-10-19T08:40:29.000Z,cern.zenodo,cern,,,,,,,"['IsSupplementTo', 'HasVersion']","[['IsVersionOf', '10.5281/zenodo.10020956']]"
10.6084/m9.figshare.15033205,Additional file 2 of Variability of multi-omics profiles in a population-based child cohort,figshare,2021,,Dataset,Creative Commons Attribution 4.0 International,"Additional file 2. Results of the variance explained by each explanatory variable in each omics feature. This file contains, for each omics layer (one per sheet), the percentage of variance explained by each explanatory variable in each omics feature.",mds,True,findable,0,0,54,1,0,2021-07-22T03:31:45.000Z,2021-07-22T03:31:47.000Z,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)'}]",['23779562 Bytes'],,,,"['References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'IsSupplementTo']",
10.6084/m9.figshare.12270167,Additional file 3 of One-year survival in acute stroke patients requiring mechanical ventilation: a multicenter cohort study,figshare,2020,,Text,Creative Commons Attribution 4.0 International,"Additional file 3. Patients characteristics and outcomes, according to the type of stroke.",mds,True,findable,0,0,33,0,0,2020-05-08T04:08:10.000Z,2020-05-08T04:08:11.000Z,figshare.ars,otjm,"Medicine,Cell Biology,Neuroscience,Biotechnology,Immunology,FOS: Clinical medicine,Biological Sciences not elsewhere classified,Science Policy,Hematology","[{'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': 'Biological Sciences not elsewhere classified'}, {'subject': 'Science Policy'}, {'subject': 'Hematology'}]",['25560 Bytes'],,,,"['References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'IsSupplementTo']",
10.5281/zenodo.11223723,"Computed Semantic clues scores for Grafematik (Magistry & Goudin, 2022)",Zenodo,2024,,Dataset,Creative Commons Attribution Share Alike 4.0 International,,api,True,findable,0,0,0,0,1,2024-05-20T18:51:03.000Z,2024-05-20T18:51:03.000Z,cern.zenodo,cern,,,,,,,['HasVersion'],
10.5281/zenodo.10912444,"Data Set for ""Alteration's control on frictional behavior and the depth of the ductile shear zone in geothermal reservoirs in volcanic arcs"" I: Lesser Antilles Volcanic Arc",Zenodo,2024,en,Dataset,Creative Commons Attribution 4.0 International,"Data set for the 48 friction experiments performed for gouge samples (altered andesitic rocks) from the Lesser Antilles used in the manuscript, ""Alteration's control on frictional behavior and the depth of the ductile shear zone in geothermal reservoirs in volcanic arcs"". This data set can be used in combination with the data set for the Cascades used in the same manuscript (doi:10.5281/zenodo.10964936). This large combined data set (of 108 frictional experiments) represents a unique opportunity to systematically study frictional behaviour in the framework of rate and state. All samples are tested in wet and dry conditions at 10, 30, and 50 MPa with velocity steps and slide-hold-slides. These two data sets have the further advantage of being performed with exactly the same protocol (same run in, same initial gouge thickness, same velocity steps, same hold periods), in the same machine, by the same operator (or by an operator who was trained and supervised by the original operator). ",api,True,findable,0,0,0,0,0,2024-05-21T15:55:31.000Z,2024-05-21T15:55:31.000Z,cern.zenodo,cern,,,,,,,['HasVersion'],"[['IsVersionOf', '10.5281/zenodo.10912444']]"
10.6084/m9.figshare.16851072,Additional file 13 of The mitochondrially-localized nucleoside diphosphate kinase D (NME4) is a novel metastasis suppressor,figshare,2021,,Image,Creative Commons Attribution 4.0 International,"Additional file 13: Fig. S7. Mitochondrial network structure in live-stained HeLa clones. HeLa cells harboring empty vector control (CTR) or expressing wild-type NDPK-D (WT) or mutant NDPK-D (BD, KD) were labeled with 100 nM Mitotracker Green. Representative confocal images are shown together with a 2.7-fold magnified detail to the right. Scale bar, 20 μm.",mds,True,findable,0,0,93,1,0,2021-10-22T04:03:41.000Z,2021-10-22T04:03:43.000Z,figshare.ars,otjm,"Biophysics,Biochemistry,Medicine,Cell Biology,Genetics,FOS: Biological sciences,Molecular Biology,Physiology,Immunology,FOS: Clinical medicine,Developmental Biology,Cancer,Hematology,Infectious Diseases,FOS: Health sciences,Computational Biology","[{'subject': 'Biophysics'}, {'subject': 'Biochemistry'}, {'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': 'Physiology'}, {'subject': 'Immunology'}, {'subject': 'FOS: Clinical medicine', 'schemeUri': 'http://www.oecd.org/science/inno/38235147.pdf', 'subjectScheme': 'Fields of Science and Technology (FOS)'}, {'subject': 'Developmental Biology'}, {'subject': 'Cancer'}, {'subject': 'Hematology'}, {'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'}]",['4286346 Bytes'],,,,"['IsIdenticalTo', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'References', 'IsSupplementTo']","[['IsIdenticalTo', '10.6084/m9.figshare.16851072']]"
10.5281/zenodo.8363117,Bulk chemical composition of rock samples used to calculate their seismic velocity at lower crustal conditions,Zenodo,2023,,Dataset,"Creative Commons Attribution 4.0 International,Open Access","These data are linked to a published study, whose aim is to compare the seismic velocity variations, derived from tomographic models (here the CIFALPS profile in the Alps, derived from Nouibat et al., 2022) and interpreted as rock transformations, with the seismic velocities of field samples. One way to predict seismic velocity at lower crustal conditions is to consider natural rocks as isotropic and to calculate their seismic properties from the relative abundance of mineral phases using their acknowledged properties (Abers and Hacker, 2016). In this process, the bulk chemical composition of the samples constitutes the starting data for this study. The subsequent work is based solely on thermodynamic models (here mainly using Holland and Powel, 1998 database) and the physical properties of the mineral phases (database from Abers and Hacker, 2016).",mds,True,findable,0,0,0,1,0,2023-09-20T11:07:28.000Z,2023-09-20T11:07:29.000Z,cern.zenodo,cern,"chemical composition, seismic velocity, lower crustal conditions, Alps","[{'subject': 'chemical composition, seismic velocity, lower crustal conditions, Alps'}]",,,,,['HasVersion'],"[['IsVersionOf', '10.5281/zenodo.8363117']]"
10.17178/emaa_para-nh3_rotation_44e467bd,"Rotation excitation of para-NH3 by H, ortho-H2 and para-H2 collisions","UGA, CNRS, CNRS-INSU, OSUG",2021,en,Dataset,"Please acknowledge the use of EMAA Database by citing the original articles in which the data were published (BibTeX format available), and adding the following sentence in your publication:
This research has made use of spectroscopic and collisional data from the EMAA database (https://emaa.osug.fr). EMAA is supported by the Observatoire des Sciences de l'Univers de Grenoble (OSUG),Creative Commons Attribution 4.0 International,Data access and use are ruled by the EMAA data policy.",34 rotation energy levels / 56 radiative transitions / 561 collisional transitions for H (20 temperatures in the range 10-200K) / 561 collisional transitions for ortho-H2 (20 temperatures in the range 10-200K) / 561 collisional transitions for para-H2 (20 temperatures in the range 10-200K),mds,True,findable,0,0,0,0,0,2021-11-17T14:02:17.000Z,2021-11-17T14:02:19.000Z,inist.osug,jbru,"target para-NH3,excitationType Rotation,collisional excitation,collider.0 H,collider.1 ortho-H2,collider.2 para-H2,astrophysics,interstellar medium,comets,circumstellar medium,gas,microwave spectroscopy,infrared spectroscopy,rotational excitation,rovibrational excitation,vibrational excitation,electronic excitation,collisional rate coefficients,fine structure,hyperfine structure","[{'subject': 'target para-NH3', 'subjectScheme': 'main'}, {'subject': 'excitationType Rotation', 'subjectScheme': 'main'}, {'subject': 'collisional excitation', 'subjectScheme': 'main'}, {'subject': 'collider.0 H', 'subjectScheme': 'var'}, {'subject': 'collider.1 ortho-H2', 'subjectScheme': 'var'}, {'subject': 'collider.2 para-H2', 'subjectScheme': 'var'}, {'subject': 'astrophysics', 'subjectScheme': 'var'}, {'subject': 'interstellar medium', 'subjectScheme': 'var'}, {'subject': 'comets', 'subjectScheme': 'var'}, {'subject': 'circumstellar medium', 'subjectScheme': 'var'}, {'subject': 'gas', 'subjectScheme': 'var'}, {'subject': 'microwave spectroscopy', 'subjectScheme': 'var'}, {'subject': 'infrared spectroscopy', 'subjectScheme': 'var'}, {'subject': 'rotational excitation', 'subjectScheme': 'var'}, {'subject': 'rovibrational excitation', 'subjectScheme': 'var'}, {'subject': 'vibrational excitation', 'subjectScheme': 'var'}, {'subject': 'electronic excitation', 'subjectScheme': 'var'}, {'subject': 'collisional rate coefficients', 'subjectScheme': 'var'}, {'subject': 'fine structure', 'subjectScheme': 'var'}, {'subject': 'hyperfine structure', 'subjectScheme': 'var'}]",,['Radex'],,,"['Cites', 'IsPartOf', 'References', 'References']",
10.5281/zenodo.832420,Data Of The Publication: Dispersive Heterodyne Probing Method For Laser Frequency Stabilization Based On Spectral Hole Burning In Rare-Earth Doped Crystals By O. Gobron Et Al.,Zenodo,2017,,Dataset,"Creative Commons Attribution 4.0,Open Access","Data corresponding to the figures of the publication ""Dispersive heterodyne probing method for laser frequency stabilization based on spectral hole burning in rare-earth doped crystals"" by O. Gobron et al. (https://doi.org/10.1364/OE.25.015539). A text file describes data in each compressed folder, please refer to the caption in the publication for more details.",,True,findable,0,0,0,0,0,2017-07-20T07:51:17.000Z,2017-07-20T07:51:17.000Z,cern.zenodo,cern,"rare earth,quantum technologies,nanoqtech,metrology,laser stabilization","[{'subject': 'rare earth'}, {'subject': 'quantum technologies'}, {'subject': 'nanoqtech'}, {'subject': 'metrology'}, {'subject': 'laser stabilization'}]",,,,,['HasVersion'],"[['IsVersionOf', '10.5281/zenodo.832420']]"
10.6084/m9.figshare.c.5814678,Clinical outcomes after treatment with direct antiviral agents: beyond the virological response in patients with previous HCV-related decompensated cirrhosis,figshare,2022,,Collection,Creative Commons Attribution 4.0 International,"Abstract Background In HCV-infected patients with advanced liver disease, the direct antiviral agents-associated clinical benefits remain debated. We compared the clinical outcome of patients with a previous history of decompensated cirrhosis following treatment or not with direct antiviral agents from the French ANRS CO22 HEPATHER cohort. Methods We identified HCV patients who had experienced an episode of decompensated cirrhosis. Study outcomes were all-cause mortality, liver-related or non-liver-related deaths, hepatocellular carcinoma, liver transplantation. Secondary study outcomes were sustained virological response and its clinical benefits. Results 559 patients met the identification criteria, of which 483 received direct antiviral agents and 76 remained untreated after inclusion in the cohort. The median follow-up time was 39.7 (IQR: 22.7–51) months. After adjustment for multivariate analysis, exposure to direct antiviral agents was associated with a decrease in all-cause mortality (HR 0.45, 95% CI 0.24–0.84, p = 0.01) and non-liver-related death (HR 0.26, 95% CI 0.08–0.82, p = 0.02), and was not associated with liver-related death, decrease in hepatocellular carcinoma and need for liver transplantation. The sustained virological response was 88%. According to adjusted multivariable analysis, sustained virological response achievement was associated with a decrease in all-cause mortality (HR 0.29, 95% CI 0.15–0.54, p < 0.0001), liver-related mortality (HR 0.40, 95% CI 0.17–0.96, p = 0.04), non-liver-related mortality (HR 0.17, 95% CI 0.06–0.49, p = 0.001), liver transplantation (HR 0.17, 95% CI 0.05–0.54, p = 0.003), and hepatocellular carcinoma (HR 0.52, 95% CI 0.29–0.93, p = 0.03). Conclusion Treatment with direct antiviral agents is associated with reduced risk for mortality. The sustained virological response was 88%. Thus, direct antiviral agents treatment should be considered for any patient with HCV-related decompensated cirrhosis. Trial registration: ClinicalTrials.gov registry number: NCT01953458.",mds,True,findable,0,0,0,0,0,2022-01-28T04:30:42.000Z,2022-01-28T04:30:43.000Z,figshare.ars,otjm,"Space Science,Medicine,Biotechnology,Chemical Sciences not elsewhere classified,Immunology,FOS: Clinical medicine,Cancer,Science Policy,Infectious Diseases,FOS: Health sciences,Virology,Computational Biology","[{'subject': 'Space Science'}, {'subject': 'Medicine'}, {'subject': 'Biotechnology'}, {'subject': 'Chemical Sciences not elsewhere classified'}, {'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'}, {'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'}, {'subject': 'Computational Biology'}]",,,,,,
10.26302/sshade/experiment_jg_20091029_003,"Vis-NIR reflectance spectra of Gode (Ogaden, Ethiopia) basalt powder",SSHADE/SOSYPOL (OSUG Data Center),2018,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 Gode (Ogaden, Ethiopia) basalt altered in hot and very arid conditions. The experiment contains spectra of the powder of the alteration rind and of the internal part of the sample.",mds,True,findable,0,0,0,0,0,2019-12-09T05:14:05.000Z,2019-12-09T05:14:06.000Z,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'}]",['2 spectra'],['ASCII'],,,"['IsPartOf', 'IsPartOf', 'IsSourceOf']",
10.17178/emaa_para-d2s_rotation_1e071ded,Rotation excitation of para-D2S by ortho-H2 and para-H2 collisions,"UGA, CNRS, CNRS-INSU, OSUG",2022,en,Dataset,"Please acknowledge the use of EMAA Database by citing the original articles in which the data were published (BibTeX format available), and adding the following sentence in your publication:
This research has made use of spectroscopic and collisional data from the EMAA database (https://emaa.osug.fr). EMAA is supported by the Observatoire des Sciences de l'Univers de Grenoble (OSUG),Creative Commons Attribution 4.0 International,Data access and use are ruled by the EMAA data policy.",25 rotation energy levels / 54 radiative transitions / 300 collisional transitions for ortho-H2 (11 temperatures in the range 5-400K) / 300 collisional transitions for para-H2 (11 temperatures in the range 5-400K),mds,True,findable,0,0,0,0,0,2023-12-07T15:52:09.000Z,2023-12-07T15:52:09.000Z,inist.osug,jbru,"target para-D2S,excitationType Rotation,collisional excitation,collider.0 ortho-H2,collider.1 para-H2,astrophysics,interstellar medium,comets,circumstellar medium,gas,microwave spectroscopy,infrared spectroscopy,rotational excitation,rovibrational excitation,vibrational excitation,electronic excitation,collisional rate coefficients,fine structure,hyperfine structure","[{'subject': 'target para-D2S', 'subjectScheme': 'main'}, {'subject': 'excitationType Rotation', 'subjectScheme': 'main'}, {'subject': 'collisional excitation', 'subjectScheme': 'main'}, {'subject': 'collider.0 ortho-H2', 'subjectScheme': 'var'}, {'subject': 'collider.1 para-H2', 'subjectScheme': 'var'}, {'subject': 'astrophysics', 'subjectScheme': 'var'}, {'subject': 'interstellar medium', 'subjectScheme': 'var'}, {'subject': 'comets', 'subjectScheme': 'var'}, {'subject': 'circumstellar medium', 'subjectScheme': 'var'}, {'subject': 'gas', 'subjectScheme': 'var'}, {'subject': 'microwave spectroscopy', 'subjectScheme': 'var'}, {'subject': 'infrared spectroscopy', 'subjectScheme': 'var'}, {'subject': 'rotational excitation', 'subjectScheme': 'var'}, {'subject': 'rovibrational excitation', 'subjectScheme': 'var'}, {'subject': 'vibrational excitation', 'subjectScheme': 'var'}, {'subject': 'electronic excitation', 'subjectScheme': 'var'}, {'subject': 'collisional rate coefficients', 'subjectScheme': 'var'}, {'subject': 'fine structure', 'subjectScheme': 'var'}, {'subject': 'hyperfine structure', 'subjectScheme': 'var'}]",,['Radex'],,,"['Cites', 'IsPartOf', 'References', 'References']",
10.5281/zenodo.11062162,Dataset for Low-loss SiGe waveguides for mid-infrared photonics fabricated on 200 mm wafers,Zenodo,2024,,Dataset,Creative Commons Attribution 4.0 International,"This dataset contains the information contained in Figures 3, 4, 5 of the related manuscript. This research dataset should be interpreted and understood in the context of the corresponding manuscript, which has been published in Optics Express with DOI:. All relevant information regarding the dataset, how it was obtained and its context is contained in the manuscript. The data correspond to the information shown in the figures of the manuscript.
Each file is in .txt format, the decimal separator is a point '.' and the column separator is a tab ';'.",api,True,findable,0,0,0,0,0,2024-04-24T20:32:05.000Z,2024-04-24T20:32:05.000Z,cern.zenodo,cern,,,,,,,"['IsPublishedIn', 'HasVersion']","[['IsVersionOf', '10.5281/zenodo.11062162']]"
10.26302/sshade/experiment_zy_20180110_002,VIS-NIR reflectance spectra of binary mixtures between the fine fraction of the JSC Lunar regolith simulant (JSC-1AF) and two types of spherical water ice particles,SSHADE/BYPASS (OSUG Data Center),2023,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.","Intimate mixtures of two types of spherical water ice particles (SPIPA-A and -B, 4.5 and 67 µm average diameter, respectively) and the JSC-1AF fine-grained fraction of JSC Lunar Regolith Simulant.",mds,True,findable,0,0,0,0,0,2023-05-04T06:58:53.000Z,2023-05-04T06:58:53.000Z,inist.sshade,mgeg,"laboratory measurement,biconical reflection,imaging,Vis,Visible,NIR,Near-Infrared,reflectance factor,Plagioclase,Vitreous matrix,Olivine,Pyroxene,water ice,solid,laboratory,tektosilicate,nesosilicate,inosilicate,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': 'Plagioclase', 'subjectScheme': 'name'}, {'subject': 'Vitreous matrix', 'subjectScheme': 'name'}, {'subject': 'Olivine', 'subjectScheme': 'name'}, {'subject': 'Pyroxene', 'subjectScheme': 'name'}, {'subject': 'water ice', 'subjectScheme': 'name'}, {'subject': 'solid', 'subjectScheme': 'family'}, {'subject': 'laboratory', 'subjectScheme': 'origin'}, {'subject': 'tektosilicate', 'subjectScheme': 'compound type'}, {'subject': 'nesosilicate', 'subjectScheme': 'compound type'}, {'subject': 'inosilicate', 'subjectScheme': 'compound type'}, {'subject': 'inorganic molecular solid', 'subjectScheme': 'compound type'}]",['11 spectra'],['ASCII'],,,"['IsPartOf', 'IsPartOf', 'IsSourceOf', 'Cites']",
10.34847/nkl.e1e41vdi,fichier0,NAKALA - https://nakala.fr (Huma-Num - CNRS),2020,,Image,,blablablablblaa,api,True,findable,0,0,0,0,0,2023-02-03T19:38:11.000Z,2023-02-03T19:38:11.000Z,inist.humanum,jbru,,,['20608 Bytes'],['image/png'],,,,
10.5281/zenodo.5835994,Ultrafast imaging recordings from the axon initial segment of neocortical layer-5 pyramidal neurons.,Zenodo,2022,en,Dataset,"Creative Commons Attribution 4.0 International,Open Access","This dataset contains imaging and whole-cell electrophysiological recordings from neocortical layer-5 pyramidal neuron from brain slices of the mouse. Electrophysiological recordings (at 20 kHz) are from the soma. Imaging data (10 kHz) are from lines along the axon initial segment (distal>proximal) with 500 nm pixel resolution. These correspond to: Sodium imaging (Figures 1 and S6). Voltage imaging (Figures 2,4,5,S4,S7) Calcium imaging (Figures 3,S3,S8). This dataset is used in the paper available online: Filipis L, Blömer LA, Montnach J, De Waard M, Canepari M. Nav1.2 and BK channels interaction shapes the action potential in the axon initial segment. bioRxiv, 2022. doi: 10.1101/2022.04.12.488116.",mds,True,findable,0,0,0,0,0,2022-10-20T13:43:28.000Z,2022-10-20T13:43:29.000Z,cern.zenodo,cern,"Nav1.2 channel,BK Ca2+-activated K+ channel,axon initial segment,action potential,neocortical layer-5 pyramidal neuron,calcium","[{'subject': 'Nav1.2 channel'}, {'subject': 'BK Ca2+-activated K+ channel'}, {'subject': 'axon initial segment'}, {'subject': 'action potential'}, {'subject': 'neocortical layer-5 pyramidal neuron'}, {'subject': 'calcium'}]",,,,,['HasVersion'],"[['IsVersionOf', '10.5281/zenodo.5835994']]"
10.5281/zenodo.3345742,"Companion code for ""When and how can Stacked Species Distribution Models predict local richness?""",Zenodo,2019,en,Software,Restricted Access,"<strong>When and how can Stacked Species Distribution Models predict local richness?</strong> This repository contains the data and code for our paper: Grenié M., Violle C, Munoz F.<em> When and how can Stacked Species Distribution Models predict local richness?</em>. submitted to <em>Ecological Indicators</em>. <strong>How to cite</strong> Please cite this compendium as: Grenié M., Violle C, Munoz F., (2019). <em>Compendium of R code and data for When and how can Stacked Species Distribution Models predict local richness?</em>. Accessed 29 july 2019. Online at <https://doi.org/10.5281/zenodo.3345743> <strong>How to download or install</strong> You can download the compendium from Zenodo https://doi.org/10.5281/zenodo.3345743 Or you can install this compendium as an R package, `comsat`, from<br> GitHub with: <pre><code># install.packages(""devtools"") remotes::install_github(""Rekyt/comsat"")</code></pre> <strong>How to run the analyses</strong> This compendium uses drake to make analyses reproducible. To redo the analyses and rebuild the manuscript run the following lines (from the `comsat` folder): <pre><code># install.packages(""devtools"") pkgload::load_all() # Load all functions included in the package make(comsat_drake_plan()) # Run Analyses</code></pre> Beware that some code make time a long time to run, and it may be useful<br> to run analyses in parallel.",mds,True,findable,0,0,0,0,0,2019-07-29T11:28:01.000Z,2019-07-29T11:28:02.000Z,cern.zenodo,cern,,,,,,,['HasVersion'],"[['IsVersionOf', '10.5281/zenodo.3345742']]"
10.57745/69unam,Tracking of Gag-mCherry spots,Recherche Data Gouv,2023,,Dataset,,"Gag-mcherry spot tracking in individual HeLa CCL2 cells or HeLA Kyoto BST2- cells. The cells were transfected by Gag/Gag-mCherry alone or Gag/Gag-mCherry along with Vps4A E228Q, CHMP4B-NS3-green, and CHMP2A-NS3-green, and then treated or not by Glecaprevir, as indicated.",mds,True,findable,84,1,0,0,0,2023-11-20T15:36:29.000Z,2023-11-20T15:56:17.000Z,rdg.prod,rdg,,,,,,,['HasPart'],
10.5281/zenodo.1003420,The Coq Proof Assistant,Zenodo,2023,en,Software,GNU Lesser General Public License v2.1 only,"Coq is a formal proof management system. It provides a formal language to write mathematical definitions, executable algorithms and theorems together with an environment for semi-interactive development of machine-checked proofs. Typical applications include the certification of properties of programming languages (e.g. the CompCert compiler certification project, the Verified Software Toolchain for verification of C programs, or the Iris framework for concurrent separation logic), the formalization of mathematics (e.g. the full formalization of the Feit-Thompson theorem, or homotopy type theory), and teaching.
Coq version 8.17 integrates a soundness fix to the Coq kernel along with a few new features and a host of improvements to the Ltac2 language and libraries. We highlight some of the most impactful changes here:
Fixed a logical inconsistency due to vm_compute in presence of side-effects in the enviroment (e.g. using Back or Fail).
It is now possible to dynamically enable or disable notations.
Support multiple scopes in Arguments and Bind Scope.
The tactics chapter of the manual has many improvements in presentation and wording. The documented grammar is semi-automatically checked for consistency with the implementation.
Fixes to the auto and eauto tactics, to respect hint priorities and the documented use of simple apply. This is a potentially breaking change.
New Ltac2 APIs, deep pattern-matching with as clauses and handling of literals, support for record types and preterms.
Move from :> to :: syntax for declaring typeclass fields as instances, fixing a confusion with declaration of coercions.
Standard library improvements.
While Coq supports OCaml 5, users are likely to experience slowdowns ranging from +10% to +50% compared to OCaml 4. Moreover, the native_compute machinery is not available when Coq is compiled with OCaml 5. Therefore, OCaml 5 support should still be considered experimental and not production-ready.
See the Changes in 8.17.0 section below for the detailed list of changes, including potentially breaking changes marked with Changed. Coq's reference manual for 8.17, documentation of the 8.17 standard library and developer documentation of the 8.17 ML API are also available.
Ali Caglayan, Emilio Jesús Gallego Arias, Gaëtan Gilbert and Théo Zimmermann worked on maintaining and improving the continuous integration system and package building infrastructure.
Erik Martin-Dorel has maintained the Coq Docker images that are used in many Coq projects for continuous integration.
Maxime Dénès, Paolo G. Giarrusso, Huỳnh Trần Khanh, and Laurent Théry have maintained the VsCoq extension for VS Code.
The opam repository for Coq packages has been maintained by Guillaume Claret, Karl Palmskog, Matthieu Sozeau and Enrico Tassi with contributions from many users. A list of packages is available at https://coq.inria.fr/opam/www/.
The Coq Platform has been maintained by Michael Soegtrop, with help from Karl Palmskog, Pierre Roux, Enrico Tassi and Théo Zimmermann.
Our current maintainers are Yves Bertot, Frédéric Besson, Ana Borges, Ali Caglayan, Tej Chajed, Cyril Cohen, Pierre Corbineau, Pierre Courtieu, Maxime Dénès, Andres Erbsen, Jim Fehrle, Julien Forest, Emilio Jesús Gallego Arias, Gaëtan Gilbert, Georges Gonthier, Benjamin Grégoire, Jason Gross, Hugo Herbelin, Vincent Laporte, Olivier Laurent, Assia Mahboubi, Kenji Maillard, Guillaume Melquiond, Pierre-Marie Pédrot, Clément Pit-Claudel, Pierre Roux, Kazuhiko Sakaguchi, Vincent Semeria, Michael Soegtrop, Arnaud Spiwack, Matthieu Sozeau, Enrico Tassi, Laurent Théry, Anton Trunov, Li-yao Xia and Théo Zimmermann. See the Coq Team face book page for more details.
The 45 contributors to the 8.17 version are: Reynald Affeldt, Tanaka Akira, Lasse Blaauwbroek, Stephan Boyer, Ali Caglayan, Cyril Cohen, Maxime Dénès, Andrej Dudenhefner, Andres Erbsen, František Farka, Jim Fehrle, Paolo G. Giarrusso, Gaëtan Gilbert, Jason Gross, Alban Gruin, Stefan Haan, Hugo Herbelin, Wolf Honore, Bodo Igler, Jerry James, Emilio Jesús Gallego Arias, Ralf Jung, Jan-Oliver Kaiser, Wojciech Karpiel, Chantal Keller, Thomas Klausner, Olivier Laurent, Yishuai Li, Guillaume Melquiond, Karl Palmskog, Sudha Parimala, Pierre-Marie Pédrot, Valentin Robert, Pierre Roux, Julin S, Dmitry Shachnev, Michael Soegtrop, Matthieu Sozeau, Naveen Srinivasan, Sergei Stepanenko, Karolina Surma, Enrico Tassi, Li-yao Xia and Théo Zimmermann.
The Coq community at large helped improve this new version via the GitHub issue and pull request system, the coq-club@inria.fr mailing list, the Discourse forum and the Coq Zulip chat.