Improvements of a Dynamic Global Vegetation Model and Simulations of Carbon and Water at an Upland-Oak Forest

The interest in the development and improvement of dynamic global vegetation models (DGVMs), which have the potential to simulate fluxes of carbon, water and nitrogen, along with changes in the vegetation dynamics, within an integrated system, has been increasing. In this paper, some numerical schem...

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Bibliographic Details
Published in:Advances in atmospheric sciences 2007-03, Vol.24 (2), p.311-322
Main Author: 毛嘉富 王斌 戴永久 F. I. WOODWARD P. J. HANSON M. R. LOMAS
Format: Article
Language:English
Subjects:
Atmospheric sciences
CARBON
ENVIRONMENTAL SCIENCES
FORESTS
GROUND WATER
Growing season
Moisture content
NITROGEN
OAKS
PLANTS
RESOLUTION
RESPIRATION
Simulation
Soil texture
Soil water
SOILS
Studies
TENNESSEE
TEXTURE
Vegetation
WATER
Water content
WATERSHEDS
丘陵橡树林
动态全局植被模型
陆地水通量
陆地碳通量
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Summary:The interest in the development and improvement of dynamic global vegetation models (DGVMs), which have the potential to simulate fluxes of carbon, water and nitrogen, along with changes in the vegetation dynamics, within an integrated system, has been increasing. In this paper, some numerical schemes and a higher resolution soil texture dataset were employed to improve the Sheffield Dynamic Global Vegetation Model (SDGVM). Using eddy covariance-based measurements, we then tested the standard version of the SDGVM and the modified version of the SDGVM. Detailed observations of daily carbon and water fluxes made at the upland oak forest on the Walker Branch Watershed in Tennessee, USA offered a unique opportunity for these comparisons. The results revealed that the modified version of the SDGVM did a reasonable job of simulating the carbon and water flux and the variation of soil water content (SWC). However, at the end of the growing season, it failed to simulate the effect of the limitations on the soil respiration dynamics and as a result underestimated this respiration. It was also noted that the modified version overestimated the increase in the SWC following summer rainfall, which was attributed to an inadequate representation of the ground water and thermal cycle.
ISSN:0256-1530
1861-9533
DOI:10.1007/s00376-007-0311-7