Decreasing relative humidity dominates a reversal of decreasing pan evaporation in mainland China after 1989
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Decreasing relative humidity dominates a reversal of decreasing pan evaporation in mainland China after 1989. / Jin, Yubin; Wang, Dashan; Feng, Yu; Wu, Jie; Cui, Wenhui; He, Xinyue; Chen, Aifang; Zeng, Zhenzhong.
I: Journal of Hydrology, Bind 608, 127641, 05.2022.Publikation: Bidrag til tidsskrift › Tidsskriftartikel › Forskning › fagfællebedømt
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TY - JOUR
T1 - Decreasing relative humidity dominates a reversal of decreasing pan evaporation in mainland China after 1989
AU - Jin, Yubin
AU - Wang, Dashan
AU - Feng, Yu
AU - Wu, Jie
AU - Cui, Wenhui
AU - He, Xinyue
AU - Chen, Aifang
AU - Zeng, Zhenzhong
N1 - Funding Information: This study was supported by the National Natural Science Foundation of China (grants no. 42071022; 42001321) and the start-up fund provided by the Southern University of Science and Technology (no. 29/Y01296122). Acknowledgement for the data support from ?Geographic Data Sharing Infrastructure, College of Urban and Environmental Science, Peking University (http://geodata.pku.edu.cn)?. Funding Information: This study was supported by the National Natural Science Foundation of China (grants no. 42071022 ; 42001321 ) and the start-up fund provided by the Southern University of Science and Technology (no. 29/Y01296122). Acknowledgement for the data support from “Geographic Data Sharing Infrastructure, College of Urban and Environmental Science, Peking University ( http://geodata.pku.edu.cn ) ”. Publisher Copyright: © 2022 Elsevier B.V.
PY - 2022/5
Y1 - 2022/5
N2 - Pan evaporation (Epan) reflects the evaporation potential of surface water and is a key indicator of atmospheric evaporative demand. Previous studies have found a substantial decrease in Epan across China, dominated by declining wind speed and solar radiation before the late 2000 s. However, how Epan responds to the recovery of wind speed and solar radiation since the late 2000 s remains unclear. Here, we investigate the spatial and temporal patterns of Epan and analyze its controlling factors, based on the daily meteorological observations during 1965–2018 at 2,018 stations over China. We find that the annual Epan in the northwest and south of China is higher than that in the northeast and central parts of China. The national mean Epan decreases significantly during 1965–1989 at a rate of −6.57 mm yr−2, then reverses at a rate of 4.58 mm yr−2. Distinct seasonal discrepancies and geographical heterogeneities in Epan trends are observed. Declining wind speed mainly contributes to the decrease in Epan before 1989, while relative humidity is shown as the dominant factor that drives the growth of Epan after the turning point. The recovery of wind speed still has significant impact on Epan variation in parts of China, while Epan is only mainly affected by solar radiation in parts of central China in autumn. Our findings highlight the importance of understanding Epan variations and driving factors, and call for precautions and adaptation actions to combat and prevent flash droughts over China, especially in the south of China.
AB - Pan evaporation (Epan) reflects the evaporation potential of surface water and is a key indicator of atmospheric evaporative demand. Previous studies have found a substantial decrease in Epan across China, dominated by declining wind speed and solar radiation before the late 2000 s. However, how Epan responds to the recovery of wind speed and solar radiation since the late 2000 s remains unclear. Here, we investigate the spatial and temporal patterns of Epan and analyze its controlling factors, based on the daily meteorological observations during 1965–2018 at 2,018 stations over China. We find that the annual Epan in the northwest and south of China is higher than that in the northeast and central parts of China. The national mean Epan decreases significantly during 1965–1989 at a rate of −6.57 mm yr−2, then reverses at a rate of 4.58 mm yr−2. Distinct seasonal discrepancies and geographical heterogeneities in Epan trends are observed. Declining wind speed mainly contributes to the decrease in Epan before 1989, while relative humidity is shown as the dominant factor that drives the growth of Epan after the turning point. The recovery of wind speed still has significant impact on Epan variation in parts of China, while Epan is only mainly affected by solar radiation in parts of central China in autumn. Our findings highlight the importance of understanding Epan variations and driving factors, and call for precautions and adaptation actions to combat and prevent flash droughts over China, especially in the south of China.
KW - Atmospheric evaporative demand
KW - Pan evaporation
KW - Relative humidity
KW - Reversal
KW - Wind speed
U2 - 10.1016/j.jhydrol.2022.127641
DO - 10.1016/j.jhydrol.2022.127641
M3 - Journal article
AN - SCOPUS:85125545434
VL - 608
JO - Journal of Hydrology
JF - Journal of Hydrology
SN - 0022-1694
M1 - 127641
ER -
ID: 307366179