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Partitioning of evapotranspiration using high‐frequency water vapor isotopic measurement over a rice paddy field
Author(s) -
Wei Zhongwang,
Yoshimura Kei,
Okazaki Atsushi,
Kim Wonsik,
Liu Zhongfang,
Yokoi Masaharu
Publication year - 2015
Publication title -
water resources research
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.863
H-Index - 217
eISSN - 1944-7973
pISSN - 0043-1397
DOI - 10.1002/2014wr016737
Subject(s) - evapotranspiration , transpiration , eddy covariance , environmental science , growing season , atmospheric sciences , paddy field , saturation (graph theory) , vegetation (pathology) , hydrology (agriculture) , soil science , ecosystem , agronomy , chemistry , ecology , geology , mathematics , medicine , biochemistry , photosynthesis , geotechnical engineering , pathology , combinatorics , biology
Partitioning ecosystem evapotranspiration ( ET ) into soil evaporation ( E ) and transpiration ( T ) is crucial for understanding hydrological processes. In this study, by using high‐frequency isotope measurements and continuous surface water measurements, we investigated the isotope ratios in soil‐vegetation‐atmosphere transfer and the physical mechanisms involved over a paddy field for a full growing season. The isotopic signals of δ ET , δ T , and δ E were determined by the Keeling plot method, surface water isotopic measurements, and the Craig‐Gordon model, respectively. The fraction of transpiration in evapotranspiration ( FT ) ranged from 0.2 to 1, with an almost continuous increase in the early growing season and a relatively constant value close to 1 later in the year. The result was supported by FT derived from simulated T and eddy correlation measured ET . The seasonal change in the transpiration fraction could be described quite well as a function of the LAI ( FT = 0.67 LAI 0.25 , R 2 = 0.80), implying that transpiration plays a dominant role in the soil‐vegetation‐atmosphere continuum during the growing season. The two end‐member uncertainty analysis suggested that further improvement in the estimation of δ T and δ ET is necessary for partitioning evapotranspiration using the isotopic method. In the estimation of δ ET , the assumptions underlying Keeling plot method were rarely met and the uncertainty was quite large. A high frequency of precise isotopic measurements in surface water was also necessary for δ T estimation. Furthermore, special care must be taken concerning the kinetic fractionation parameter in the Craig and Gordon Equation for δ E estimation under low‐LAI conditions. The results demonstrated the robustness of using isotope measurements for partitioning evapotranspiration.