Temporal variability of evapotranspiration and its response to westerly and monsoon circulation over the Tibetan Plateau
Westerlies and monsoons converge over the Tibetan Plateau, yet their influence on evapotranspiration in the area is largely unknown. We analyzed the variability of evapotranspiration (ET) over the Tibetan Plateau and its response to the large-scale westerly and monsoon circulation. The results show...
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| creator | Yang, Zesu Yue, Ping Zhang, Yu Zhang, Qiang Zhang, Liang Zeng, Jian Qi, Yulei |
| description | Westerlies and monsoons converge over the Tibetan Plateau, yet their influence on evapotranspiration in the area is largely unknown. We analyzed the variability of evapotranspiration (ET) over the Tibetan Plateau and its response to the large-scale westerly and monsoon circulation. The results show that the annual mean ET is 414.2 ± 18.32 mm over the Tibetan Plateau. The annual ET has large interannual variability and exhibits trends that differ significantly among sub-regions (southwest, southeast, north regions). The Webster-Yang index (WYI) (Westerly index, WI) showed a fluctuating decreasing (increasing) trend with an interannual variability of 22.1% (6.4%) during the study period. The ensemble empirical mode decomposition analysis (EEMD) demonstrates that the WI dominates the 5-year scale variation of ET in the southeast, the WYI dominates the 5-year scale variation of ET in the southwest and the interannual scale variation of ET in the north, and the interaction between WYI and WI dominates the inter-decadal scale variation of ET in the southwest and southeast. WYI and WI regulate ET by influencing climatic environmental conditions. In the southeast region, the enhanced WYI significantly increases the temperature, which induces the depletion of soil moisture and thus reduces ET. These processes play a dominant role in regulating ET, while the temperature increase, improving vegetation greenness and consequently accelerating ET, plays a secondary role. In the southwest, the increase in WYI increases temperature and decreases the vapor pressure difference (VPD), as well as the rising temperature increases soil moisture and consequently ET. These processes dominate in WYI regulating ET, while the VPD decrease, reducing ET, plays a secondary role. In the northern region, the enhanced WYI decreases VPD, and thus reduces ET. |
| doi_str_mv | 10.1007/s00704-022-04202-5 |
| format | Article |
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We analyzed the variability of evapotranspiration (ET) over the Tibetan Plateau and its response to the large-scale westerly and monsoon circulation. The results show that the annual mean ET is 414.2 ± 18.32 mm over the Tibetan Plateau. The annual ET has large interannual variability and exhibits trends that differ significantly among sub-regions (southwest, southeast, north regions). The Webster-Yang index (WYI) (Westerly index, WI) showed a fluctuating decreasing (increasing) trend with an interannual variability of 22.1% (6.4%) during the study period. The ensemble empirical mode decomposition analysis (EEMD) demonstrates that the WI dominates the 5-year scale variation of ET in the southeast, the WYI dominates the 5-year scale variation of ET in the southwest and the interannual scale variation of ET in the north, and the interaction between WYI and WI dominates the inter-decadal scale variation of ET in the southwest and southeast. WYI and WI regulate ET by influencing climatic environmental conditions. In the southeast region, the enhanced WYI significantly increases the temperature, which induces the depletion of soil moisture and thus reduces ET. These processes play a dominant role in regulating ET, while the temperature increase, improving vegetation greenness and consequently accelerating ET, plays a secondary role. In the southwest, the increase in WYI increases temperature and decreases the vapor pressure difference (VPD), as well as the rising temperature increases soil moisture and consequently ET. These processes dominate in WYI regulating ET, while the VPD decrease, reducing ET, plays a secondary role. In the northern region, the enhanced WYI decreases VPD, and thus reduces ET.</description><identifier>ISSN: 0177-798X</identifier><identifier>EISSN: 1434-4483</identifier><identifier>DOI: 10.1007/s00704-022-04202-5</identifier><language>eng</language><publisher>Vienna: Springer Vienna</publisher><subject>Analysis ; Annual variations ; Aquatic Pollution ; Atmospheric Protection/Air Quality Control/Air Pollution ; Atmospheric Sciences ; Climate science ; Climatology ; Depletion ; Earth and Environmental Science ; Earth Sciences ; Empirical analysis ; Environmental conditions ; Evapotranspiration ; Interannual variability ; Moisture effects ; Monsoon circulation ; Monsoons ; Original Paper ; Plateaus ; Soil moisture ; Soil temperature ; Temperature ; Temperature rise ; Temporal variability ; Temporal variations ; Vapor pressure ; Vapour pressure ; Variation ; Vegetation ; Waste Water Technology ; Water Management ; Water Pollution Control ; Westerlies ; Wind</subject><ispartof>Theoretical and applied climatology, 2022-11, Vol.150 (3-4), p.1111-1129</ispartof><rights>The Author(s), under exclusive licence to Springer-Verlag GmbH Austria, part of Springer Nature 2022. 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We analyzed the variability of evapotranspiration (ET) over the Tibetan Plateau and its response to the large-scale westerly and monsoon circulation. The results show that the annual mean ET is 414.2 ± 18.32 mm over the Tibetan Plateau. The annual ET has large interannual variability and exhibits trends that differ significantly among sub-regions (southwest, southeast, north regions). The Webster-Yang index (WYI) (Westerly index, WI) showed a fluctuating decreasing (increasing) trend with an interannual variability of 22.1% (6.4%) during the study period. The ensemble empirical mode decomposition analysis (EEMD) demonstrates that the WI dominates the 5-year scale variation of ET in the southeast, the WYI dominates the 5-year scale variation of ET in the southwest and the interannual scale variation of ET in the north, and the interaction between WYI and WI dominates the inter-decadal scale variation of ET in the southwest and southeast. WYI and WI regulate ET by influencing climatic environmental conditions. In the southeast region, the enhanced WYI significantly increases the temperature, which induces the depletion of soil moisture and thus reduces ET. These processes play a dominant role in regulating ET, while the temperature increase, improving vegetation greenness and consequently accelerating ET, plays a secondary role. In the southwest, the increase in WYI increases temperature and decreases the vapor pressure difference (VPD), as well as the rising temperature increases soil moisture and consequently ET. These processes dominate in WYI regulating ET, while the VPD decrease, reducing ET, plays a secondary role. 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Plateau</atitle><jtitle>Theoretical and applied climatology</jtitle><stitle>Theor Appl Climatol</stitle><date>2022-11-01</date><risdate>2022</risdate><volume>150</volume><issue>3-4</issue><spage>1111</spage><epage>1129</epage><pages>1111-1129</pages><issn>0177-798X</issn><eissn>1434-4483</eissn><abstract>Westerlies and monsoons converge over the Tibetan Plateau, yet their influence on evapotranspiration in the area is largely unknown. We analyzed the variability of evapotranspiration (ET) over the Tibetan Plateau and its response to the large-scale westerly and monsoon circulation. The results show that the annual mean ET is 414.2 ± 18.32 mm over the Tibetan Plateau. The annual ET has large interannual variability and exhibits trends that differ significantly among sub-regions (southwest, southeast, north regions). The Webster-Yang index (WYI) (Westerly index, WI) showed a fluctuating decreasing (increasing) trend with an interannual variability of 22.1% (6.4%) during the study period. The ensemble empirical mode decomposition analysis (EEMD) demonstrates that the WI dominates the 5-year scale variation of ET in the southeast, the WYI dominates the 5-year scale variation of ET in the southwest and the interannual scale variation of ET in the north, and the interaction between WYI and WI dominates the inter-decadal scale variation of ET in the southwest and southeast. WYI and WI regulate ET by influencing climatic environmental conditions. In the southeast region, the enhanced WYI significantly increases the temperature, which induces the depletion of soil moisture and thus reduces ET. These processes play a dominant role in regulating ET, while the temperature increase, improving vegetation greenness and consequently accelerating ET, plays a secondary role. In the southwest, the increase in WYI increases temperature and decreases the vapor pressure difference (VPD), as well as the rising temperature increases soil moisture and consequently ET. These processes dominate in WYI regulating ET, while the VPD decrease, reducing ET, plays a secondary role. In the northern region, the enhanced WYI decreases VPD, and thus reduces ET.</abstract><cop>Vienna</cop><pub>Springer Vienna</pub><doi>10.1007/s00704-022-04202-5</doi><tpages>19</tpages><orcidid>https://orcid.org/0000-0001-8447-8279</orcidid></addata></record> |
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| subjects | Analysis Annual variations Aquatic Pollution Atmospheric Protection/Air Quality Control/Air Pollution Atmospheric Sciences Climate science Climatology Depletion Earth and Environmental Science Earth Sciences Empirical analysis Environmental conditions Evapotranspiration Interannual variability Moisture effects Monsoon circulation Monsoons Original Paper Plateaus Soil moisture Soil temperature Temperature Temperature rise Temporal variability Temporal variations Vapor pressure Vapour pressure Variation Vegetation Waste Water Technology Water Management Water Pollution Control Westerlies Wind |
| title | Temporal variability of evapotranspiration and its response to westerly and monsoon circulation over the Tibetan Plateau |
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