Abstract
Drought impacts carbon and water fluxes of terrestrial ecosystems, which are strongly coupled. However, the magnitudes of response of carbon and water fluxes to drought are dependent on many processes, which are more complex than previously expected. Southern China experienced regional climatic perturbation events in the past decade and a two-year drought in 2009–2010. We used a terrestrial ecosystem model coupled with remotely sensed observations and metrological data to simulate the variations of net primary productivity (NPP), evapotranspiration (ET), and water-use efficiency (WUE) (i.e., NPP/ET) in south-western China during the period 2001–2010. Using the standard precipitation index (SPI) classifying different drought stresses, we also quantified the effect of drought on the ecosystem by comparing changes in modelled estimates of monthly WUE, NPP and ET under normal (i.e., baseline) and drought conditions (i.e., 2009 and 2010). The results indicated that NPP and ET showed synchronized declines in drought periods, with time-lag effects. Furthermore, drought-induced NPP decline was larger than ET reduction. An increasing trend in WUE from the moderate to extreme drought classes occurred not only in baseline conditions but also in drought conditions. Especially in the extreme drought period (January, 2010), WUE for the forest ecosystem typically showed a positive response to drought, indicating a drought-resilient forest ecosystem. Our study has important implications for understanding climate extreme effects on the carbon and water cycle of the forest ecosystem.
Highlights
Persistent droughts reduce vegetation greenness, biomass, productivity, and increase tree mortality [1,2,3,4,5,6,7,8]
The sustainability of terrestrial carbon and water cycles is strongly affected by the frequency and intensity of large-scale drought events, and all these disturbances have substantial impacts on ecosystem structure, species composition and function [16,17,18]
We found that there existed a 4- to 6-month lag between most severe drought stage that occurred occurred in January and maximum decline in
Summary
Persistent droughts reduce vegetation greenness, biomass, productivity, and increase tree mortality [1,2,3,4,5,6,7,8]. The sustainability of terrestrial carbon and water cycles is strongly affected by the frequency and intensity of large-scale drought events, and all these disturbances have substantial impacts on ecosystem structure, species composition and function [16,17,18]. They are of great importance in exploring the impacts of droughts on the regional carbon budget and water resources and improving our ability to refine water management. Water availability controls plant photosynthesis and influences plant growth, and affects net primary productivity (NPP), evapotranspiration (ET) and water-use efficiency (WUE) [19,20]
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