A spatial-explicit dynamic vegetation model that couples carbon, water, and nitrogen processes for arid and semiarid ecosystems

Arid and semiarid ecosystems, or dryland, are important to global biogeochemical cycles. Dryland's community structure and vegetation dynamics as well as biogeochemical cycles are sensitive to changes in climate and atmospheric composition. Vegetation dynamic models has been applied in global change...

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Bibliographic Details
Published in:Journal of arid land 2013-03, Vol.5 (1), p.102-117
Main Authors: Zhang, Chi, Li, ChaoFan, Chen, Xi, Luo, GePing, Li, LongHui, Li, XiaoYu, Yan, Yan, Shao, Hua
Format: Article
Language:English
Subjects:
Earth and Environmental Science
Geography
Physical Geography
Plant Ecology
Sustainable Development
半干旱生态系统
土壤水分
植被模型
氮矿化
生物地球化学循环
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Summary:Arid and semiarid ecosystems, or dryland, are important to global biogeochemical cycles. Dryland's community structure and vegetation dynamics as well as biogeochemical cycles are sensitive to changes in climate and atmospheric composition. Vegetation dynamic models has been applied in global change studies, but the com- plex interactions among the carbon (C), water, and nitrogen (N) cycles have not been adequately addressed in the current models. In this study, a process-based vegetation dynamic model was developed to study the responses of dryland ecosystems to environmental changes, emphasizing on the interactions among the C, water, and N proc- esses. To address the interactions between the C and water processes, it not only considers the effects of annual precipitation on vegetation distribution and soil moisture on organic matter (SOM) decomposition, but also explicitly models root competition for water and the water compensation processes. To address the interactions between C and N processes, it models the soil inorganic mater processes, such as N mineralization/immobilization, denitrifica- tion/nitrification, and N leaching, as well as the root competition for soil N. The model was parameterized for major plant functional types and evaluated against field observations.
ISSN:1674-6767
DOI:10.1007/s40333-013-0146-2