Litcius/Paper detail

Soil Evaporation Stress Determines Soil Moisture‐Evapotranspiration Coupling Strength in Land Surface Modeling

Jianzhi Dong, Paul A. Dirmeyer, Fangni Lei, Martha C. Anderson, Thomas Holmes, Christopher Hain, Wade T. Crow

2020Geophysical Research Letters71 citationsDOI

Abstract

Abstract Model‐based estimates of soil moisture (SM)‐evapotranspiration (ET) coupling strength ( ρ ) vary widely and are prone to bias. Here we apply numerical modeling and remote sensing to identify the process‐level source of modeled ρ bias with the goal of improving the fidelity of current Earth system models. Results illustrate that modeled ρ is most strongly determined by soil evaporation ( E ) stress, and (generally positive) ρ modeling bias is attributable to the oversimplification of soil texture impacts on E stress. Based on new remotely sensed estimates of ρ , we demonstrate that removing ρ bias via a single optimized E stress parameter leads to improved ET accuracy and resolves a well‐known modeling bias in the partitioning of ET into E and T. As such, we highlight the importance of the stress function relating E and SM and its central role in regulating land‐atmosphere coupling processes impacting local climate.

Topics & Concepts

EvapotranspirationEnvironmental scienceCoupling (piping)Soil scienceEvaporationSoil textureStress (linguistics)Potential evaporationClimate modelWater contentMoistureClimate changeRemote sensingSoil waterGeologyMeteorologyGeotechnical engineeringMaterials scienceEcologyGeographyMetallurgyPhilosophyBiologyOceanographyLinguisticsSoil Moisture and Remote SensingPlant Water Relations and Carbon DynamicsSoil and Unsaturated Flow