Abstract
Evapotranspiration (ET) is one of the key components of the global hydrological cycle. Many models have been established to obtain an accurate estimation of ET, but the uncertainty of each model has not been satisfactorily addressed, and the weight determination in multi-model simulation methods remains unclear. In this study, the Bayesian model averaging (BMA) method was adopted to tackle this issue. We explored the combination of four surface energy balance (SEB) models (SEBAL, SSEB, S-SEBI and SEBS) with the BMA method by using Landsat 8 images over two study areas in China, the Huailai flux station (semiarid region) and the Sidaoqiao flux station (arid/semiarid region), and the data from two stations were used as validation for this method. The performances of SEB models and different BMA methods is revealed by three statistical parameters (i.e., the coefficient of determination (R2), root mean squared error (RMSE), and the Nash-Sutcliffe efficiency coefficient (NSE)). We found the best performing SEB model was SEBAL, with an R2 of 0.609 (0.672), RMSE of 1.345 (0.876) mm/day, and NSE of 0.407 (0.563) at Huailai (Sidaoqiao) station. Compared with the four individual SEB models, each of the BMA methods (fixed, posterior inclusion probability, or random) can provide a more accurate and reliable simulation result. Similarly, in Huailai (Sidaoqiao) station, the best performing BMA random model provided an R2 of 0.750 (0.796), RMSE of 0.902 (0.602) mm/day, and NSE of 0.746 (0.793). We conclude that the BMA method outperformed the four SEB models alone and obtained a more accurate prediction of ET in two cropland areas, which provides important guidance for water resource allocation and management in arid and semiarid regions.
Highlights
Evapotranspiration (ET) is a process of transformation of water from liquid to gaseous form [1].It is a sophisticated process that links water transport from the land surface to the atmosphere.ET plays an important part in the global hydrological cycle, accounting for about two-thirds of the terrestrial precipitation [2,3,4]
Four surface energy balance (SEB) models coupled with the Bayesian model averaging (BMA) method are investigated in this study, and several points
Four SEB models coupled with the BMA method are investigated in this study, and several can be concluded from the results of the two stations, namely: first, for single SEB model validation, points can be concluded from the results of the two stations, namely: first, for single SEB model the surface energy balance algorithm for land (SEBAL) and simplified surface energy balance (SSEB) performed better than surface energy balance index (SEBI) and surface energy balance system (SEBS) with higher R2, lower root mean square error (RMSE), and greater validation, the SEBAL and SSEB performed better than SEBI and SEBS with higher R2, lower RMSE, Nash–Sutcliffe efficiency coefficient (NSE)
Summary
Evapotranspiration (ET) is a process of transformation of water from liquid to gaseous form [1].It is a sophisticated process that links water transport from the land surface to the atmosphere.ET plays an important part in the global hydrological cycle, accounting for about two-thirds of the terrestrial precipitation [2,3,4]. The accurate estimation of ET provides an effective approach in understanding the hydrological cycle process [5,6], planning cropland water consumption [7], and environmental evaluation, especially in arid and semiarid areas [8], as well as exploring the laws of crop growth progress and predicting the tendency of global climate change [9]. Water abundance determines the range of the evapotranspiration rate (the ratio of actual ET to potential ET), and the physiological characteristics of plants constitute the complex physical mechanism of ET as a natural process [12]
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