Assessing the variations of evapotranspiration and its environmental controls over a subalpine wetland valley in China

•We examined the environmental control of evapotranspiration (ET) over a wetland.•Available energy (net radiation, Rn) mainly controlled ET at a daily scale.•Seasonally, Rn, air temperature (Ta) and vapor pressure deficit (VPD) controlled ET.•Interannual variation in ET was mainly controlled by Ta a...

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Bibliographic Details
Published in:Journal of hydrology (Amsterdam) 2023-02, Vol.617, p.129058, Article 129058
Main Authors: Xiang, Jiao, Hayat, Muhammad, Yu Qiu, Guo, Xiao, Weiyang, Xu, Xianli, Mao, Peng, Yan, Chunhua, Qin, Longjun
Format: Article
Language:English
Subjects:
Bowen ratio
Evapotranspiration
High-altitude wetlands
Multiple timescales
Rising temperature
Water balance
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Summary:•We examined the environmental control of evapotranspiration (ET) over a wetland.•Available energy (net radiation, Rn) mainly controlled ET at a daily scale.•Seasonally, Rn, air temperature (Ta) and vapor pressure deficit (VPD) controlled ET.•Interannual variation in ET was mainly controlled by Ta and precipitation (P).•ET used most of P leads to decreasing runoff and streams drying up in Jiuzhaigou valley. Dynamics in long-term evapotranspiration (ET) and its controlling variables are essential for understanding how a high-altitude wetlands ecosystem responds to climate change. The rising temperature is expected to agitate the regional hydrological cycle and water balance, particularly in the subalpine wetland valley of Jiuzhaigou, located in the transition zone between the northeast Qinghai-Tibet Plateau and the Sichuan Basin, Southwest China. Here, we used growing season multi-year (2013–2021) Bowen ratio data to assess the variability in ET and its key controlling parameters at different timescales in Jiuzhaigou valley. This study also explored the ratio of ET to precipitation (P). The wetland daily mean ET varied from 0.06 to 6.77 mm d−1, with a mean value of 2.64 mm d−1 for the nine years. Fluctuations in daily ET were primarily driven by available energy (net radiation, Rn), explaining 86 % of the variation. Seasonal patterns in ET were largely similar to environmental parameters, i.e., Rn, air temperature (Ta), and vapor pressure deficit (VPD), peaking in August with an interannual monthly mean value of 3.48 mm d−1. Interannual monthly mean ET had a strong positive linear relationship with Rn, Ta, and VPD, while there was no significant correlation with P on a growing season basis. Furthermore, monthly ET was shown to be regulated by Ta largely in high-temperature months and minimally in low-temperature months. The growing season ET varied interannually, and the ET to P ratio (i.e., ET/P) ranged between 0.52 and 1.16. Interannual variation in annual ET was controlled by Ta and P, which individually explained 73 and 61 % of the variation, respectively. The multiple regression model indicated that Ta and P together elucidated 92 % of the variation in annual ET. The increased sensitivity (e.g., regression slopes) of ET to P over 2014–2021 indicates that ET consumed most of P, which leads to decreasing runoff and streams drying up. This study clarifies the temporal dynamics in ET for wetlands and its environmental controls at multiple timescales. It is
ISSN:0022-1694
1879-2707
DOI:10.1016/j.jhydrol.2022.129058