TY - JOUR
T1 - Influence of vegetation, temperature, and water content on soil carbon distribution and mineralization in four high arctic soils
AU - Elberling, Bo
AU - Jakobsen, Bjarne H.
AU - Berg, Peter
AU - Søndergaard, Jens
AU - Sigsgaard, Charlotte
PY - 2004/1/1
Y1 - 2004/1/1
N2 - Soil organic matter distributions, reservoirs, and mineralization rates in tundra soils are important factors for understanding biogeochemical carbon cycling. This study focuses on spatial trends and environmental controls of soil carbon distribution and microbial soil respiration in 4 tundra vegetation communities in an arctic valley in NE-Greenland (74°N), including Dryas and Cassiope heaths, Salix snow bed, and fen vegetation. Measured total soil organic carbon in the upper 50 cm averaged (±SD) 11.0 ± 1.5 kg C m -2 with spatial variations strongly affected by vegetation, hydrology, and buried organic layers. Observed soil CO2 concentrations and effluxes were simulated with a steady-state diffusion model using laboratory measured CO2 productions as input. Simulated CO 2 profiles and CO2 effluxes (up to 3 μmol CO 2 m-2 s-1) agreed with field observations and revealed the importance of both vegetation- and depth-specific CO2 production and CO2 diffusion for understanding the spatial variation in near-surface soil CO2 gas dynamics. These results confirm that molecular diffusion dominates gas transport in the studied soils; but also that the complexity of CO2 production/transport coupled to soil heterogeneity (in particular the litter layer) complicates the application of soil-diffusion models to estimate seasonal trends of soil gas effluxes.
AB - Soil organic matter distributions, reservoirs, and mineralization rates in tundra soils are important factors for understanding biogeochemical carbon cycling. This study focuses on spatial trends and environmental controls of soil carbon distribution and microbial soil respiration in 4 tundra vegetation communities in an arctic valley in NE-Greenland (74°N), including Dryas and Cassiope heaths, Salix snow bed, and fen vegetation. Measured total soil organic carbon in the upper 50 cm averaged (±SD) 11.0 ± 1.5 kg C m -2 with spatial variations strongly affected by vegetation, hydrology, and buried organic layers. Observed soil CO2 concentrations and effluxes were simulated with a steady-state diffusion model using laboratory measured CO2 productions as input. Simulated CO 2 profiles and CO2 effluxes (up to 3 μmol CO 2 m-2 s-1) agreed with field observations and revealed the importance of both vegetation- and depth-specific CO2 production and CO2 diffusion for understanding the spatial variation in near-surface soil CO2 gas dynamics. These results confirm that molecular diffusion dominates gas transport in the studied soils; but also that the complexity of CO2 production/transport coupled to soil heterogeneity (in particular the litter layer) complicates the application of soil-diffusion models to estimate seasonal trends of soil gas effluxes.
UR - http://www.scopus.com/inward/record.url?scp=15044339286&partnerID=8YFLogxK
U2 - 10.1657/1523-0430(2004)036[0528:IOVTAW]2.0.CO;2
DO - 10.1657/1523-0430(2004)036[0528:IOVTAW]2.0.CO;2
M3 - Journal article
AN - SCOPUS:15044339286
SN - 1523-0430
VL - 36
SP - 528
EP - 538
JO - Arctic, Antarctic, and Alpine Research
JF - Arctic, Antarctic, and Alpine Research
IS - 4
ER -