(Table 1) Bioclimatic subzones and soil characteristics along the Yamal Arctic Transect, northwestern Siberia

Sustainability of tundra vegetation under changing climate on the Yamal Peninsula, northwestern Siberia, home to the world's largest area of reindeer husbandry, is of crucial importance to the local native community. An integrated investigation is needed for better understanding of the effects...

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Bibliographic Details
Main Authors: Yu, Qin, Epstein, Howard E, Walker, Donald A
Format: Dataset
Language:English
Published: PANGAEA 2009
Subjects:
Active layer depth
Carbon
Density
dry bulk
Event label
International Polar Year (2007-2008)
International Polar Year 2007-2008
IPY
IPY-4
KH
Kharasavey1
Kharasavey2a
LA
Laborovaya1
Laborovaya2
Latitude of event
Longitude of event
MULT
Multiple investigations
Nitrogen
organic
particulate
total
Sand
Silt
Site
Size fraction < 0.002 mm
clay
Time coverage
VaskinyDachi1
VaskinyDachi2
VaskinyDachi3
VD
Yamal Peninsula
northwestern Siberia
Zone
biogeographic
Arctic
Climate change
International Polar Year
reindeer husbandry
Tundra
Siberia
Online Access:https://doi.pangaea.de/10.1594/PANGAEA.842562
https://doi.org/10.1594/PANGAEA.842562
Description
Summary:Sustainability of tundra vegetation under changing climate on the Yamal Peninsula, northwestern Siberia, home to the world's largest area of reindeer husbandry, is of crucial importance to the local native community. An integrated investigation is needed for better understanding of the effects of soils, climate change and grazing on tundra vegetation in the Yamal region. In this study we applied a nutrient-based plant community model - ArcVeg - to evaluate how two factors (soil organic nitrogen (SON) levels and grazing) interact to affect tundra responses to climate warming across a latitudinal climatic gradient on the Yamal Peninsula. Model simulations were driven by field-collected soil data and expected grazing patterns along the Yamal Arctic Transect (YAT), within bioclimate subzones C (high arctic), D (northern low arctic) and E (southern low arctic). Plant biomass and NPP (net primary productivity) were significantly increased with warmer bioclimate subzones, greater soil nutrient levels and temporal climate warming, while they declined with higher grazing frequency. Temporal climate warming of 2 °C caused an increase of 665 g/m**2 in total biomass at the high SON site in subzone E, but only 298 g/m**2 at the low SON site. When grazing frequency was also increased, total biomass increased by only 369 g/m**2 at the high SON site in contrast to 184 g/m**2 at the low SON site in subzone E. Our results suggest that high SON can support greater plant biomass and plant responses to climate warming, while low SON and grazing may limit plant response to climate change. In addition to the first order factors (SON, bioclimate subzones, grazing and temporal climate warming), interactions among these significantly affect plant biomass and productivity in the arctic tundra and should not be ignored in regional scale studies.

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