TY - JOUR
T1 - Estimation of annual forest evapotranspiration from a coniferous plantation watershed in Japan (2)
T2 - Comparison of eddy covariance, water budget and sap-flow plus interception loss
AU - Shimizu, Takanori
AU - Kumagai, Tomo'omi
AU - Kobayashi, Masahiro
AU - Tamai, Koji
AU - Iida, Shin'ichi
AU - Kabeya, Naoki
AU - Ikawa, Reo
AU - Tateishi, Makiko
AU - Miyazawa, Yoshiyuki
AU - Shimizu, Akira
N1 - Funding Information:
Maintenance of the KHEW is supported by the Kyushu Research Center of the Forestry and Forest Products Research Institute (FFPRI) and the National Forests in Kyushu Office. This work was financially supported by the Ministry of Agriculture, Forestry and Fisheries, Japan through a research project entitled “Development of technologies for mitigation and adaptation to climate change in Agriculture, Forestry and Fisheries (A-8)” and also supported by Grants-in-Aid for Scientific Research (Nos. 17380096 and 17510011 ) from the Ministry of Education, Science and Culture, Japan. The authors are grateful to Prof. Masakazu Suzuki of The University of Tokyo, Prof. Delphis F. Levia of The University of Delaware, and Dr. Kazuki Nanko of FFPRI for support of this study. The authors also thank Dr. Yasuhiro Ohnuki and Dr. Shoji Noguchi of FFPRI for helpful instruction, and Dr. Hiroaki Hagino of FFPRI and Dr. Natsuko Yoshifuji of Kyoto University for providing field information. Further, we appreciate the thoughtful comments and advice of three anonymous reviewers.
Publisher Copyright:
© 2014 Elsevier B.V.
PY - 2015/3/1
Y1 - 2015/3/1
N2 - Evapotranspiration (ET) was estimated from a planted coniferous forest in southwestern Japan by applying three methods: the eddy covariance method; the measurement of rainfall (P) and runoff (Q) in a small watershed; and a combination of rainfall interception loss (IC), upper canopy transpiration based on a sap-flux density measurement in Japanese cedar (Cryptomeria Japonica D. Don) stands (EUC), and modeled sub-canopy ET (ESC). After inverse multiplication of the energy imbalance ratio, ET by the eddy covariance method (ETEC) was 839.9mm in 2007 and 811.8mm in 2008. The yearly values of P-Q were partially affected by P in the previous autumn. After continuous data collection for more than 5years, P-Q became stable. The 9-year (2000-2008) average P-Q, which was considered most reliable in this study, was 897.5mmy-1. The cumulative ETEC during the daylight hours from the right stream bank, covered mainly with large Japanese cedars, was 894.1mm from April 2007 to March 2008. The value was almost the same as that calculated as the components sum (ETCOMP=IC+EUC+ESC: 911.4mm), and the comparison suggested that the annual totals of ETEC with an energy imbalance correction provide a reliable estimate of ET in a forest stand on a complex topography. Spatial variation in the watershed was likely caused by differences in soil water retention at each slope position. The slight difference in annual ETEC in 2007 compared with 2008 was attributed to differences in the radiative energy input. In the monthly-weekly analysis, ETCOMP was frequently higher than ETEC after heavy rainfall, while ETEC was higher under dry conditions and during active ET. Even under dry canopy conditions, daily ETEC was often higher than EUC+ESC. The results suggested a time-lag in evaporation from the ecosystem and/or under-estimated ETEC after rainfall.
AB - Evapotranspiration (ET) was estimated from a planted coniferous forest in southwestern Japan by applying three methods: the eddy covariance method; the measurement of rainfall (P) and runoff (Q) in a small watershed; and a combination of rainfall interception loss (IC), upper canopy transpiration based on a sap-flux density measurement in Japanese cedar (Cryptomeria Japonica D. Don) stands (EUC), and modeled sub-canopy ET (ESC). After inverse multiplication of the energy imbalance ratio, ET by the eddy covariance method (ETEC) was 839.9mm in 2007 and 811.8mm in 2008. The yearly values of P-Q were partially affected by P in the previous autumn. After continuous data collection for more than 5years, P-Q became stable. The 9-year (2000-2008) average P-Q, which was considered most reliable in this study, was 897.5mmy-1. The cumulative ETEC during the daylight hours from the right stream bank, covered mainly with large Japanese cedars, was 894.1mm from April 2007 to March 2008. The value was almost the same as that calculated as the components sum (ETCOMP=IC+EUC+ESC: 911.4mm), and the comparison suggested that the annual totals of ETEC with an energy imbalance correction provide a reliable estimate of ET in a forest stand on a complex topography. Spatial variation in the watershed was likely caused by differences in soil water retention at each slope position. The slight difference in annual ETEC in 2007 compared with 2008 was attributed to differences in the radiative energy input. In the monthly-weekly analysis, ETCOMP was frequently higher than ETEC after heavy rainfall, while ETEC was higher under dry conditions and during active ET. Even under dry canopy conditions, daily ETEC was often higher than EUC+ESC. The results suggested a time-lag in evaporation from the ecosystem and/or under-estimated ETEC after rainfall.
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U2 - 10.1016/j.jhydrol.2014.12.021
DO - 10.1016/j.jhydrol.2014.12.021
M3 - Article
AN - SCOPUS:84923008500
SN - 0022-1694
VL - 522
SP - 250
EP - 264
JO - Journal of Hydrology
JF - Journal of Hydrology
ER -