Friday, August 6, 2010
Exhibit Hall A, David L Lawrence Convention Center
Qiang Yu1, Quansheng Chen2, James J. Elser3, Nianpeng He2, Honghui Wu2, Shouren Zhang2, Jianguo Wu4, Yongfei Bai5 and Xingguo Han6, (1)Department of Biology, Colorado State University, Fort Collins, CO, (2)Institute of Botany, Chinese Academy of Sciences, (3)School of Life Sciences, Arizona State University, Tempe, AZ, (4)School of Life Sciences&Global Institute of Sustainability, Arizona State University, Tempe, AZ, (5)Institute of Botany, Chinese Academy of Sciences, Beijing, China, (6)State Key Laboratory of Forest and Soil Ecology, Instituted of Applied Ecology, Chinese Academy of Sciences, Shenyang, China
Background/Question/Methods
Ecosystem structure, functioning, and stability have been a focus of ecological and environmental sciences during the past two decades. However, the mechanisms that link them are not well understood. We took three approaches to test the relationship of stoichiometric homeostasis with species dominance, ecosystem functioning, and stability. These involved a two-year field N and P addition experiment, a long-term (27 years) observational data set of grassland excluded from sheep grazing, and a 1200-km spatial transect across the Inner Mongolia grassland.
Results/Conclusions
Here we show that species-level stoichiometric homeostasis was consistently positively correlated with dominance and stability on both two-year and 27-year temporal scales and over a 1200-km spatial transect. At the community level, stoichiometric homeostasis was also positively correlated with ecosystem function and stability in most cases. Thus, homeostatic species tend to have high and stable biomass; consequently, ecosystems dominated by more homeostatic species have higher productivity and greater stability. By modulating organism responses to key environmental drivers, stoichiometric homeostasis appears to be a major mechanism responsible for grassland ecosystem structure, functioning, and stability.