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  • Wiley  (51)
  • PANGAEA
  • Ramat-Gan: Bar-Ilan University, Department of Economics
  • 2010-2014  (56)
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Year
  • 1
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    (Supplement Table S4) Vegetation biomass according to sorted categories for releves along the North America Arctic bioclimate gradient (2014)
    PANGAEA
    Details
    Publication Date: 2023-01-13
    Keywords: Alaska, USA; Deadhorse; ENV; Environmental investigation; Event label; Franklin_Bluffs; Green_Cabin; Happy_Valley; Howe_Island; Isachsen2; Latitude of event; Longitude of event; Mould_Bay2; Queen Elizabeth Islands, Canada NWT; Sagwon; Sample code/label; Vegetation biomass; West_Dock
    Type: Dataset
    Format: text/tab-separated-values, 3555 data points
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    DATA PANGAEA
  • 2
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    (Supplement Table S2) Abundance of plant species (raw data) for 147 releves along the North America Arctic bioclimate gradient (2001-2006) (2011)
    PANGAEA
    Details
    Publication Date: 2023-11-01
    Keywords: Abietinella abietina; Agonimia gelatinosa; Alaska, USA; Alectoria nigricans; Alectoria ochroleuca; Allocetraria madreporiformis; Aloina brevirostris; Alopecurus alpinus; Amblystegium longicuspus; Amblystegium serpens; Anaptychia bryorum; Anastrophyllum minutum; Andromeda polifolia; Androsace chamaejasme; Aneura pinguis; Antennaria friesiana; Antennaria sp.; Anthelia juratzkana; Arctagrostis latifolia; Arctoa anderssonii; Arctocetraria nigricascens; Arctomia delicatula; Arctostaphylos alpina; Arctous rubra; Arnellia fennica; Artemisia borealis; Arthrorhaphis vacillans; Asahinea chrysantha; Astragalus alpinus; Astragalus richardsonii; Astragalus umbellatus; Aulacomnium acuminatum; Aulacomnium palustre; Aulacomnium turgidum; Baeomyces carneus; Baeomyces rufus; Barbilophozia barbata; Barbilophozia binsteadii; Barbilophozia hyperborea; Barbilophozia kunzeana; Barbula unguiculata; Bare ground; Bartramia ithyphylla; Betula nana; Biatora subduplex; Biatora vernalis; Biatorella conspersa; Bistorta vivipara; Blepharostoma trichophyllum; Brachythecium mildeanum; Brachythecium turgidum; Braya glabella var. glabella; Braya glabella var. purpurascens; Braya humilis; Bryocaulon divergens; Bryodina rhypariza; Bryoerythrophyllum recurvirostre; Bryonora castanea; Bryum arcticum; Bryum argenteum; Bryum caespiticium; Bryum pseudotriquetrum; Bryum rutilans; Bryum sp.; Bryum subneodamense; Bryum teres; Bryum wrightii; Bucegia romanica; Calamagrostis canadensis; Calamagrostis sp.; Callialaria curvicaule; Calliergon giganteum; Calliergon sp.; Caloplaca ammiospila; Caloplaca cerina; Caloplaca phaeocarpella; Caloplaca sp.; Caloplaca tetraspora; Caloplaca tiroliensis; Caloplaca tornoensis; Caloplaca xanthostigmoidea; Calypogeja muelleriana; Calypogeja sphagnicola; Campylium arcticum; Campylium chrysophyllum; Campylium longicuspus; Campylium polygamum; Campylium stellatum; Candelariella placodizans; Candelariella sp.; Candelariella terrigena; Cardamine bellidifolia; Cardamine digitata; Carex aquatilis; Carex atrofusca; Carex bigelowii; Carex capillaris; Carex fuliginosa var. misandra; Carex heleonastes; Carex membranacea; Carex microchaeta; Carex rariflora; Carex rotundata; Carex rupestris; Carex scirpoidea; Carex sp.; Carex vaginata var. quasivaginata; Cassiope tetragona; Catapyrenium cinereum; Catapyrenium sp.; Catoscopium nigritum; Cephalozia bicuspidata; Cephalozia pleniceps; Cephaloziella arctogena; Cephaloziella grimsulana; Cephaloziella varians; Cerastium arcticum; Cerastium beeringianum; Ceratodon heterophyllus; Ceratodon purpureus; Cetraria aculeata; Cetraria inermis; Cetraria islandica; Cetraria laevigata; Cinclidium arcticum; Cinclidium latifolium; Cirriphyllum cirrosum; Cladina arbuscula; Cladina mitis; Cladina rangiferina; Cladina stygia; Cladonia alaskana; Cladonia amaurocraea; Cladonia cenotea; Cladonia chlorophaea; Cladonia coccifera; Cladonia cornuta; Cladonia cyanipes; Cladonia deformis; Cladonia fimbriata; Cladonia gracilis; Cladonia gracilis var. elongata; Cladonia macroceras; Cladonia pleurota; Cladonia pocillum; Cladonia pyxidata; Cladonia scabriuscula; Cladonia sp.; Cladonia squamosa; Cladonia subfurcata; Cladonia sulphurina; Cladonia trassii; Cladonia uncialis; Cochlearia groenlandica; Collema ceraniscum; Collema sp.; Collema tenax; Collema undulatum; Conostomum tetragonum; Cratoneuron sp.; Ctenidium molluscum; Ctenidium procerrimum; Cyrtomnium hymenophylloides; Dactylina arctica; Dactylina beringica; Dactylina ramulosa; Deadhorse; Dicranum acutifolium; Dicranum angustum; Dicranum bonjeanii; Dicranum elongatum; Dicranum fragilifolium; Dicranum groenlandicum; Dicranum sp.; Dicranum spadiceum; Dicranum undulatum; Didymodon asperifolius; Didymodon rigidulus; Didymodon rigidulus var. icmadophilus; Didymodon sp.; Didymodon spadiceus; Distichium capillaceum; Distichium inclinatum; Ditrichum flexicaule; Draba alpina; Draba cinerea; Draba nivalis; Draba oblongata; Draba sp.; Draba subcapitata; Drepanocladus aduncus; Drepanocladus brevifolius; Drepanocladus sendtneri; Drepanocladus sp.; Dryas integrifolia; Elymus alaskanus var. alaskanus; Elymus alaskanus var. hyperarcticus; Empetrum nigrum; Encalypta alpina; Encalypta longicolla; Encalypta procera; Encalypta rhaptocarpa; Encalypta sp.; Encalypta vulgaris; Endocarpon pusillum; Entodon concinnus; ENV; Environmental investigation; Epilobium sp.; Equisetum arvense; Equisetum variegatum; Eriophorum angustifolium var. triste; Eriophorum vaginatum; Eurhynchium pulchellum; Event label; Evernia perfragilis; Festuca baffinensis; Festuca brachyphylla; Festuca hyperborea; Fissidens arcticus; Fissidens bryoides; Flavocetraria cucullata; Flavocetraria nivalis; Franklin_Bluffs; Fulgensia bracteata; Fuscopannaria praetermissa; Green_Cabin; Grimmia sp.; Gymnomitrion concinnatum; Gymnomitrion corallioides; Happy_Valley; Hedysarum alpinum; Hennediella heimii; Hennediella heimii var. arctica; Howe_Island; Hulteniella integrifolium; Hylocomium splendens; Hymenostylium recurvirostre; Hypnum bambergeri; Hypnum cupressiforme; Hypnum holmenii; Hypnum revolutum; Hypnum sp.; Hypnum subimponens; Hypnum vaucheri; Hypogymnia subobscura; Isachsen2; Isopterygiopsis pulchella; Japewia tornoensis; Juncus biglumis; Juncus castaneus; Juncus triglumis; Jungermannia polaris; Kiaeria cf. blyttii; Kobresia myosuroides; Lagotis glauca; Latitude of event; Lecanora epibryon; Lecanora geophila; Lecanora luteovernalis; Lecidea ramulosa; Lecidella wulfenii; Leiocolea collaris; Lepraria cf. vouauxii; Lepraria neglecta; Lepraria sp.; Leptobryum pyriforme; Leptogium gelatinosum; Leptogium lichenoides; Leptogium sp.; Limprichtia revolvens; Lloydia serotina; Longitude of event; Lopadium pezizoideum; Lophozia badensis; Lophozia collaris; Lophozia excisa; Lophozia jurensis; Lophozia longiflora; Lophozia polaris; Lophozia savicziae; Lophozia silvicola; Lophozia sp.; Lophozia ventricosa; Lophozia wenzelii; Lupinus arcticus; Luzula confusa; Luzula nivalis; Masonhalea richardsonii; Meesia longiseta; Meesia triquetra; Meesia uliginosa; Megalaria jemtlandica; Megaspora verrucosa; Micarea incrassata; Minuartia arctica; Minuartia rossii; Minuartia rubella; Mnium marginatum; Mnium thomsonii; Mould_Bay2; Mycoblastus sanguinarius; Myurella julacea; Myurella tenerrima; Nephroma arcticum; Nephroma expallidum; Nostoc commune; Ochrolechia androgyna; Ochrolechia cf. inaequatula; Ochrolechia frigida; Ochrolechia inaequatula; Ochrolechia sp.; Ochrolechia upsaliensis; Odontoshisma macounii; Orthilia secunda; Orthothecium chryseum; Orthothecium strictum; Orthothecium varia; Orthotrichum speciosum; Oxyria digyna; Oxytropis arctica; Oxytropis arctobia; Oxytropis borealis; Oxytropis maydelliana; Oxytropis sp.; Packera heterophylla; Papaver macounii; Papaver radicatum; Papaver sp.; Parmelia omphalodes var. glacialis; Parrya arctica; Parrya nudicaulis; Pedicularis albolabiata; Pedicularis arctoeuropaea; Pedicularis capitata; Pedicularis labradorica; Pedicularis lanata; Pedicularis langsdorfii; Pedicularis lapponica; Pedicularis oederi; Pedicularis sudetica; Pellia endivifolia; Peltigera aphthosa; Peltigera canina; Peltigera didactyla; Peltigera frippii; Peltigera leucophlebia; Peltigera malacea; Peltigera neopolydactyla; Peltigera polydactylon; Peltigera rufescens; Peltigera scabrosa; Peltigera sp.; Peltigera venosa; Pertusaria atra; Pertusaria bryontha; Pertusaria dactylina; Pertusaria glomerata; Pertusaria octomela; Pertusaria panyrga; Petasites frigidus; Phaeorrhiza nimbosa; Philonotis tomentella; Physconia muscigena; Placopsis gelida; Placynthium nigrum; Plagiochila asplenioides; Pleurozium schreberi; Poa abbreviata; Poa alpigena; Poa arctica var. lanata; Poa sp.; Pogonatum urnigerum; Pohlia beringiensis; Pohlia cruda; Pohlia drummondii; Pohlia nutans; Pohlia sp.; Polyblastia bryophila; Polyblastia sendtneri; Polyblastia terrestris; Polychidium muscicola; Polytrichastrum alpinum; Polytrichastrum alpinum var. alpinum; Polytrichum hyperboreum; Polytrichum piliferum; Polytrichum sp.;
    Type: Dataset
    Format: text/tab-separated-values, 70093 data points
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  • 3
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    (Supplement Table S3b) Environmental and soil data for releves along the North America Arctic bioclimate gradient (2011)
    PANGAEA
    Details
    Publication Date: 2023-07-10
    Keywords: -; Active layer depth; Alaska, USA; Bare ground; Blue-green algae; Carbon/Nitrogen ratio; Deadhorse; Density; ENV; Environmental investigation; Equisetum; Event label; Forbs; Franklin_Bluffs; Grass, cover; Green_Cabin; Happy_Valley; HEIGHT above ground; Horizon; Howe_Island; Index; Isachsen2; Latitude 2; Lichen; Marchantiophyta; Moss; Mould_Bay2; Normalized Difference Vegetation Index; pH; Plant community; Queen Elizabeth Islands, Canada NWT; Sagwon; Sample code/label; Sand; Shrubs; Silt; Size fraction 〈 0.002 mm, clay; Snow thickness; Soil moisture; Vegetation, cover; Vegetation biomass; Zone, biogeographic
    Type: Dataset
    Format: text/tab-separated-values, 9758 data points
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  • 4
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    Arctic aboveground tundra biomass dynamics between 1982 and 2010 (2012)
    PANGAEA
    In:  Supplement to: Epstein, Howard E; Raynolds, Martha K; Walker, Donald A; Bhatt, Uma S; Tucker, Compton J; Pinzon, Jorge E (2012): Dynamics of aboveground phytomass of the circumpolar Arctic tundra during the past three decades. Environmental Research Letters, 7(1), 12 pp, https://doi.org/10.1088/1748-9326/7/1/015506
    Details
    Publication Date: 2023-12-13
    Description: Numerous studies have evaluated the dynamics of Arctic tundra vegetation throughout the past few decades, using remotely sensed proxies of vegetation, such as the normalized difference vegetation index (NDVI). While extremely useful, these coarse-scale satellite-derived measurements give us minimal information with regard to how these changes are being expressed on the ground, in terms of tundra structure and function. In this analysis, we used a strong regression model between NDVI and aboveground tundra phytomass, developed from extensive field-harvested measurements of vegetation biomass, to estimate the biomass dynamics of the circumpolar Arctic tundra over the period of continuous satellite records (1982-2010). We found that the southernmost tundra subzones (C-E) dominate the increases in biomass, ranging from 20 to 26%, although there was a high degree of heterogeneity across regions, floristic provinces, and vegetation types. The estimated increase in carbon of the aboveground live vegetation of 0.40 Pg C over the past three decades is substantial, although quite small relative to anthropogenic C emissions. However, a 19.8% average increase in aboveground biomass has major implications for nearly all aspects of tundra ecosystems including hydrology, active layer depths, permafrost regimes, wildlife and human use of Arctic landscapes. While spatially extensive on-the-ground measurements of tundra biomass were conducted in the development of this analysis, validation is still impossible without more repeated, long-term monitoring of Arctic tundra biomass in the field.
    Keywords: International Polar Year (2007-2008); IPY
    Type: Dataset
    Format: application/zip, 4 datasets
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  • 5
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    Plant species, biomass and environmental characteristics of relevés along the North America Arctic bioclimate gradient (2011)
    PANGAEA
    In:  Supplement to: Walker, Donald A; Kuss, Patrick; Epstein, Howard E; Kade, Anja N; Vonlanthen, Corinne M; Raynolds, Martha K; Daniëls, Frederikus J A (2011): Vegetation of zonal patterned-ground ecosystems along the North America Arctic bioclimate gradient. Applied Vegetation Science, 14(4), 440-463, https://doi.org/10.1111/j.1654-109X.2011.01149.x
    Details
    Publication Date: 2023-12-13
    Description: Question: How do interactions between the physical environment and biotic properties of vegetation influence the formation of small patterned-ground features along the Arctic bioclimate gradient? Location: At 68° to 78°N: six locations along the Dalton Highway in arctic Alaska and three in Canada (Banks Island, Prince Patrick Island and Ellef Ringnes Island). Methods: We analysed floristic and structural vegetation, biomass and abiotic data (soil chemical and physical parameters, the n-factor [a soil thermal index] and spectral information [NDVI, LAI]) on 147 microhabitat releves of zonalpatterned-ground features. Using mapping, table analysis (JUICE) and ordination techniques (NMDS). Results: Table analysis using JUICE and the phi-coefficient to identify diagnostic species revealed clear groups of diagnostic plant taxa in four of the five zonal vegetation complexes. Plant communities and zonal complexes were generally well separated in the NMDS ordination. The Alaska and Canada communities were spatially separated in the ordination because of different glacial histories and location in separate floristic provinces, but there was no single controlling environmental gradient. Vegetation structure, particularly that of bryophytes and total biomass, strongly affected thermal properties of the soils. Patterned-ground complexes with the largest thermal differential between the patterned-ground features and the surrounding vegetation exhibited the clearest patterned-ground morphologies.
    Keywords: International Polar Year (2007-2008); IPY
    Type: Dataset
    Format: application/zip, 3 datasets
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  • 6
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    Tall shrub and tree expansion in Siberian tundra ecotones since the 1960s (2013)
    Wiley
    Details
    Publication Date: 2013-09-21
    Description: Circumpolar expansion of tall shrubs and trees into Arctic tundra is widely thought to be occurring as a result of recent climate warming, but little quantitative evidence exists for northern Siberia, which encompasses the world's largest forest-tundra ecotonal belt. We quantified changes in tall shrub and tree canopy cover in eleven, widely-distributed Siberian ecotonal landscapes by comparing very-high-resolution photography from the Cold War-era “Gambit” and “Corona” satellite surveillance systems (1965-1969) with modern imagery. We also analyzed within-landscape patterns of vegetation change to evaluate the susceptibility of different landscape components to tall shrub and tree increase. The total cover of tall shrubs and trees increased in nine of eleven ecotones. In northwest Siberia, alder ( Alnus ) shrubland cover increased 5.3 – 25.9% in five ecotones. In Taymyr and Yakutia, larch ( Larix ) cover increased 3.0 – 6.7% within three ecotones, but declined 16.8% at a fourth ecotone due to thaw of ice-rich permafrost. In Chukotka, the total cover of alder and dwarf pine ( Pinus ) increased 6.1% within one ecotone and was little-changed at a second ecotone. Within most landscapes, shrub and tree increase was linked to specific geomorphic settings, especially those with active disturbance regimes such as permafrost patterned-ground, floodplains, and colluvial hillslopes. Mean summer temperatures increased at most ecotones since the mid-1960s, but rates of shrub and tree canopy cover expansion were not strongly correlated with temperature trends and were better correlated with mean annual precipitation. We conclude that shrub and tree cover is increasing in tundra ecotones across most of northern Siberia, but rates of increase vary widely regionally and at the landscape-scale. Our results indicate that extensive changes can occur within decades in moist, shrub-dominated ecotones, as in northwest Siberia, while changes are likely to occur much more slowly in the highly continental, larch-dominated ecotones of central and eastern Siberia. This article is protected by copyright. All rights reserved.
    Print ISSN: 1354-1013
    Electronic ISSN: 1365-2486
    Topics: Biology , Energy, Environment Protection, Nuclear Power Engineering , Geography
    Published by Wiley
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  • 7
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    A watershed-scale assessment of a process soil CO2 production and efflux model (2011)
    Wiley
    Details
    Publication Date: 2011-05-28
    Description: Growing season soil CO2 efflux is known to vary laterally by as much as seven fold within small subalpine watersheds (
    Print ISSN: 0043-1397
    Electronic ISSN: 1944-7973
    Topics: Architecture, Civil Engineering, Surveying , Geography
    Published by Wiley on behalf of American Geophysical Union (AGU).
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  • 8
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    Soil Nitrogen Transformations Associated with Small Patterned-Ground Features along a North American Arctic Transect (2012)
    Wiley
    Details
    Publication Date: 2012-09-08
    Description: ABSTRACT Small patterned-ground features (PGFs) in the Arctic have unique soil properties that vary with latitude and may greatly affect tundra biogeochemistry. Because nitrogen availability can strongly limit arctic vegetation growth, we examined how soil nitrogen transformations differ between PGFs and the surrounding inter-PGF tundra along an arctic latitudinal gradient. We collected soils at eight sites from the Alaskan Low Arctic to the Canadian High Arctic. The soils were incubated for 21 days at 9 °C and 15 °C and analysed for changes in total inorganic nitrogen, nitrate and extractable organic nitrogen (EON). We found greater nitrogen immobilisation in the surrounding inter-PGF soils than in the PGF soils. Along the latitudinal gradient, differences in net nitrogen mineralisation and EON cycling between PGF and inter-PGF soils were strongly influenced by the presence of a pH boundary within the Low Arctic and the transition between the High and Low Arctic, with greater immobilisation in the nonacidic and Low Arctic sites, respectively. Incubation temperature affected EON flux but did not affect net nitrogen mineralisation or nitrification. These results show that spatial heterogeneity at several scales can influence soil nitrogen dynamics, and is therefore an important influence on arctic ecosystem function. Copyright © 2012 John Wiley & Sons, Ltd.
    Print ISSN: 1045-6740
    Electronic ISSN: 1099-1530
    Topics: Geography , Geosciences
    Published by Wiley
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  • 9
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    Integrating social and political risk into ROI calculations (2011)
    Wiley
    Details
    Publication Date: 2011-03-15
    Print ISSN: 1055-7571
    Electronic ISSN: 1520-6483
    Topics: Energy, Environment Protection, Nuclear Power Engineering , Economics
    Published by Wiley
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  • 10
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    Active Faults and Nuclear Power Plants (2014)
    Wiley
    Details
    Publication Date: 2014-01-29
    Description: The destruction of the Fukushima Daiichi Nuclear Power Plant (NPP) following the March 2011 Tohoku earthquake and tsunami brought into sharp focus the susceptibility of NPPs to natural hazards. This is not a new issue—seismic hazard has affected the development of plants in the United States, and volcanic hazard was among the reasons for not commissioning the Bataan NPP in the Philippines [ Connor et al ., 2009].
    Print ISSN: 0096-3941
    Electronic ISSN: 2324-9250
    Topics: Geosciences
    Published by Wiley on behalf of American Geophysical Union (AGU).
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