Abstract
The Xinjiang Uyghur Autonomous Region of China has experienced significant land cover and climate change since the beginning of the 21st century. However, a reasonable simulation of evapotranspiration (ET) and its response to environmental factors are still unclear. For this study, to simulate ET and its response to climate and land cover change in Xinjiang, China from 2001 to 2012, we used the Common Land Model (CoLM) by adding irrigation effects for cropland and modifying root distributions and the root water uptake process for shrubland. Our results indicate that mean annual ET from 2001 to 2012 was 131.22 (±21.78) mm/year and demonstrated no significant trend (p = 0.12). The model simulation also indicates that climate change was capable of explaining 99% of inter-annual ET variability; land cover change only explained 1%. Land cover change caused by the expansion of croplands increased annual ET by 1.11 mm while climate change, mainly resulting from both decreased temperature and precipitation, reduced ET by 21.90 mm. Our results imply that climate change plays a dominant role in determining changes in ET, and also highlight the need for appropriate land-use strategies for managing water sources in dryland ecosystems within Xinjiang.
Highlights
Due to global warming and human activities, acceleration and intensification of the global water cycle is becoming an undisputed fact [1, 2]
Our results indicated that modified Common Land Model (CoLM) simulations were more comparable to observations at the FK (Fukang) site than the default CoLM
The CoLM modified using both the hydraulic redistribution (HR) and Root Water Uptake Function (RWUF) produced a more significant linear relationship than that modified by HR, with R2 = 0.72, p
Summary
Due to global warming and human activities, acceleration and intensification of the global water cycle is becoming an undisputed fact [1, 2]. Evapotranspiration (ET), an important component of hydrological processes, plays a critical role in the global water budget. Oki and Kanae [3] reported that global land ET returns approximately 60% of annual land precipitation to the atmosphere, indicating that asynchronous changes in ET may lead to severe hydrological deficits [4]. ET consumes more than half of solar radiation in the form of latent heat [5].
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