Modeling and prediction of high-precision global evapotranspiration: based on a different model of physical relationships

Abstract

Read online

The interchange of water vapor between the land and the atmosphere is influenced by actual evapotranspiration (AET). A nonlinear model (AET-SWC-PET-GPP, ASPG) was developed in this study to combine potential evapotranspiration (PET), soil water content (SWC), and gross primary productivity (GPP) in order to quantitatively estimate AET. The Fluxnet Network 2015 global flux station dataset was used to compare the AET models (AET-SWC, AS; AET-SWC-PET, ASP and AET-SWC-PET2, ASP2) with various combinations of influencing factors. The results show that the simulation accuracy of the ASPG model is higher than that of AS, ASP, and ASP2, with improvements in a coefficient of determination (R2) of 45.3, 8.1, and 5.7%, respectively.The ASPG performed well for various vegetation types, geographical regions, and time scales. It was also discovered that the fitting coefficients vary depending on the type of vegetation, each with its own range of values. The ASPG model put forth in this study can be used to more effectively estimate AET quantitatively on a global scale and can serve as a theoretical foundation for the accurate calculation of global evapotranspiration and the wise use of water resources. HIGHLIGHTS Introduction of a new model (ASPG) that integrates potential evapotranspiration (PET), soil water content (SWC), and gross primary productivity (GPP) to quantitatively estimate actual evapotranspiration (AET).; Additionally, the study emphasizes the variability of fitting coefficients based on vegetation type, suggesting the model's adaptability to different ecosystems.;

Keywords

• actual evapotranspiration
• gross primary productivity
• potential evapotranspiration
• relationship analysis
• soil water content