Estimating evapotranspiration from soil moisture using the improved soil water balance method in cold mountainous areas

IF 3.1 Q2 GEOSCIENCES, MULTIDISCIPLINARY Journal of Hydrology X Pub Date : 2023-08-01 DOI:10.1016/j.hydroa.2023.100154
Yao Lai , Jie Tian , Weiming Kang , Shuchen Guo , Yongxu Zhou , Chansheng He
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Abstract

Evapotranspiration (ET) is critical for ecosystem protection and water services, especially in the mountainous areas of arid and semi-arid watersheds. The lysimeter and Eddy Covariance (EC) methods are widely used for directly measuring ET, but are difficult to install and apply in mountainous areas with complex topography. The commonly used indirect methods for estimating ET, such as the Penman-Monteith (PM) method, present significant challenges in mountainous areas with scarce data. The simple soil water balance (SWB) method, which estimates ET from soil moisture dynamics, is another reliable and simple method for estimating ET. However, a drawback of the original SWB method is that it assumes soil moisture depletion only occurs through ET, ignoring the process of deep percolation. This restriction limits the applicability of the SWB method. In this study, we improve the SWB method (ISWB) by incorporating a deep percolation module into the soil water balance equation. Subsequently, we compare the estimated ET obtained from the ISWB, the Food and Agriculture Organization (FAO)-56 PM, and the Hargreaves-Samani (HS) methods with the observed ET. Results show that the ISWB method for estimating ET performs better when using the soil moisture of the 0–25 cm and below layers, compared to the 0–20 cm and above layers. Meanwhile, there is no significant difference in performance between using the soil moisture of the 0–25 cm layer and the soil layers below 25 cm. In addition, ignoring interception evaporation has an obvious influence on ET estimation using the ISWB. Furthermore, the comparison indicated that the performance of the ISWB method is superior to that of the FAO-56 PM and HS methods in the study areas. Our study shows that the ISWB method has significant potential for ET estimation in data-scarce and topographic-complex mountainous areas.

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利用改进的土壤水分平衡法估算寒冷山区土壤水分蒸散量
蒸散发对生态系统保护和水服务至关重要,特别是在干旱和半干旱流域的山区。蒸渗仪和涡动相关(Eddy Covariance, EC)方法被广泛用于直接测量ET,但在地形复杂的山区安装和应用困难。常用的间接估算ET的方法,如Penman-Monteith (PM)方法,在数据稀缺的山区面临着重大挑战。简单土壤水分平衡法(simple soil water balance, SWB)是估算ET的另一种简单可靠的方法,它通过土壤水分动态来估算ET。然而,原有的SWB方法有一个缺点,即它假设土壤水分耗竭只通过ET发生,而忽略了深层渗流过程。这一限制限制了SWB方法的适用性。在这项研究中,我们改进了SWB方法(ISWB),将深层渗透模块纳入土壤水分平衡方程。随后,我们将ISWB、FAO -56 PM和Hargreaves-Samani (HS)方法估算的ET与观测的ET进行了比较。结果表明,ISWB方法在0-25 cm及以下土层的估算ET优于0-20 cm及以上土层的估算ET。同时,0 ~ 25 cm土层与25 cm以下土层的土壤水分利用性能无显著差异。此外,忽略拦截蒸发对利用ISWB估算蒸散发有明显影响。此外,比较表明,ISWB方法在研究区域的性能优于FAO-56 PM和HS方法。研究表明,ISWB方法在数据稀缺和地形复杂的山区具有很大的应用潜力。
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来源期刊
Journal of Hydrology X
Journal of Hydrology X Environmental Science-Water Science and Technology
CiteScore
7.00
自引率
2.50%
发文量
20
审稿时长
25 weeks
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