Open Access
Comparison of evapotranspiration estimates using the water balance and the eddy covariance methods
Author(s) -
Denager Tanja,
Looms Majken C.,
Sonnenborg Torben O.,
Jensen Karsten H.
Publication year - 2020
Publication title -
vadose zone journal
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.036
H-Index - 81
ISSN - 1539-1663
DOI - 10.1002/vzj2.20032
Subject(s) - eddy covariance , evapotranspiration , latent heat , sensible heat , energy balance , lysimeter , environmental science , water balance , available energy , flux (metallurgy) , groundwater recharge , bowen ratio , heat flux , atmospheric sciences , meteorology , soil science , soil water , energy (signal processing) , mathematics , heat transfer , geography , mechanics , geology , groundwater , chemistry , physics , statistics , thermodynamics , aquifer , ecosystem , ecology , biology , geotechnical engineering , organic chemistry
Abstract The eddy covariance method estimates the energy flux of latent heat for evapotranspiration. However, imbalance between the land surface energy output and input is a well‐known fact. Energy balance closure is most commonly not achieved, and therefore the eddy covariance method potentially underestimates actual evapotranspiration. Notwithstanding, the method is one of the most established measurement techniques for estimating evapotranspiration. Here, evapotranspiration from eddy covariance (ET EC ) is cross‐checked with evapotranspiration calculated as the residual of the water balance (ET wb ). The water balance closure using ET EC is simultaneously validated. Over a 6‐yr period, all major terms of the water balance are measured including precipitation, recharge from percolation lysimeters, and soil moisture content from a cosmic‐ray neutron sensor, a capacitance sensor network, and time domain reflectometry (TDR), respectively. In addition, we estimate their respective uncertainties. The study demonstrates that both monthly and yearly ET EC and ET wb compare well and that the water balance is closed when ET EC is used. Concurrently, incoming available energy (net radiation minus ground heat flux) on average exceeds the turbulent energy fluxes (latent heat flux and sensible heat flux) by 31%, exposing the energy–surface imbalance. Consequently, the imbalance in the energy balance using the eddy covariance method must, to a lesser degree, be caused by errors in the latent heat estimates but can mainly be attributed to errors in the other energy flux components.