Evaluation of the rescaled complementary principle in the estimation of evaporation on the Tibetan Plateau

Accurate quantification of the terrestrial water balance can improve our knowledge of regional water cycle changes, and deepen our understanding of evaporation in hydrological cycle and under climate change. However, sparse observation networks on the Tibetan Plateau (TP) prevent the reliable estima...

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Bibliographic Details
Published in:Science of The Total Environment
Main Authors: Yang Wenjing, Wang Yibo, Liu Xin, Zhao Haipeng, Shao Rui, Wang Genxu
Format: Article in Journal/Newspaper
Language:English
Published: ELSEVIER 2020
Subjects:
Generalized nonlinear complementary relationship
Tibetan Plateau
Evaporation
Maximum apparent potential evaporation
CLIMATE-CHANGE
ALPINE GRASSLAND
PAN EVAPORATION
2-SOURCE MODEL
BARE SOIL
WATER
EVAPOTRANSPIRATION
LAKE
PERMAFROST
CHINA
Environmental Sciences & Ecology
Environmental Sciences
Kendall
permafrost
Online Access:http://ir.imde.ac.cn/handle/131551/33556
https://doi.org/10.1186/s12870-020-02496-z
Description
Summary:Accurate quantification of the terrestrial water balance can improve our knowledge of regional water cycle changes, and deepen our understanding of evaporation in hydrological cycle and under climate change. However, sparse observation networks on the Tibetan Plateau (TP) prevent the reliable estimates of actual evaporation. Based on the China regional surface Meteorological Feature Dataset (CMFD) and the Global Land Surface Satellite (GLASS) product, we adopted the latest rescaled nonlinear complementary relationship (CR) to calculate the monthly actual evaporation (E) from 1982 to 2015. We analyzed the spatio-temporal variability of the annual E on the entire TP, and explored the main meteorological factors controlling the annual E and the regulation of multiyear average annual E in different vegetation zones from southeast to northwest. Our results indicated that the net radiation (R-n) and E exhibited a favorable agreement with monthly changes of the observed values; and E estimated by the CR explained 79-96% variation of the eddy covariance flux measurements. The multiyear average E was 373.12 mm yr (1) and displayed similar spatial patterns of decreasing from southeast to northwest with two remote sensing products (GLDAS_VIC, GLEAM_v3.3) and one hydrological model (Budyko). Additionally, based on the Mann-Kendall trend test, there were 21.56% of the TP with significant upward trend of annual E which mainly distributed in the area with dense glaciers. The Nyenchen Tanglha Mountains and Pamirs Plateau area had the most obvious upward trend, with up to over 6 mm yr(-1). In a relative sense, the key meteorological elements which affected annual E on the TP were relative humidity (RH) (r = 0.63) and R-n (r = 0.56). (C) 2019 Elsevier B.V. All rights reserved.

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