Interactive and individual effects of multi-factor controls on water use efficiency in Central Asian ecosystems
Open Access
- 29 April 2020
- journal article
- research article
- Published by IOP Publishing in Environmental Research Letters
- Vol. 15 (8), 084025
- https://doi.org/10.1088/1748-9326/ab8e8b
Abstract
Water use efficiency (WUE) characterizes the relationship between water dissipation and carbon sequestration. Knowledge of WUE dynamics and its responses to complex climate controls are prerequisites for addressing the challenges of future climate change and human disturbance of wild lands. Owing to a lack of experimental observations and the complexity of quantifying the individual and interactive effects of different environmental factors, the mechanism of WUE dynamics and the spatiotemporal characteristics of WUE in Central Asian ecosystems remain unclear. Here, a specific Arid Ecosystem Model was used to assess WUE dynamics under environmental stresses, specifically isolating and identifying proprietary features from complex coupling effects, across different ecosystems in Central Asia from 1980 to 2014. WUE declined in southern Xinjiang but exhibited an upward trend in the Tianshan Mountains and northern Kazakhstan. Precipitation and CO2 controlled WUE of 39% and 54% of Central Asia, respectively. The factor analysis showed that the negative effects of climate change were largely compensated by the CO2 fertilization effect, and their interaction produced negative feedback to WUE. This resulted in inhibition of the CO2 fertilization effect during long droughts. The negative effects of warming included increased water stress and enhanced evapotranspiration from vegetation. Based on variations in precipitation and net primary production, we determined that southern Xinjiang and the Turgay Plateau were environmentally vulnerable areas. Our study provides guidance regarding how ecologically fragile regions in Central Asia might cope with environmental pressures under extreme climate change in the future.Funding Information
- Taishan Scholars Program of Shandong, China (No. ts201712071)
- Xinjiang Natural Science Foundation (2019D01A31)
- Program B for Outstanding PhD Candidate of Nanjing University (201902B076)
- National Natural Science Funds of China (41861018)
- Natural science youth fund of Xinjiang education department (XJEDU2020Y041)
- Open Fund of Shandong Provincial Key Laboratory of Water and Soil Conservation and Environmental Protection, China (No.STKF201912)
- Xinjiang institute of engineering doctoral fund (2018xgy092105)
- National R&D Key Program of China (2016YFA0600202)
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