Effect of climate change on the trends of evaporation of phreatic water from bare soil in Huaibei Plain, China

SHANG Man-ting; LIU Pei-gui; LEI Chao; LIU Ming-chao; WU Liang

Volume 5 Issue 3

Sep. 2017

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Article Navigation > Journal of Groundwater Science and Engineering > 2017 > 5(3): 213-221

SHANG Man-ting, LIU Pei-gui, LEI Chao, et al. 2017: Effect of climate change on the trends of evaporation of phreatic water from bare soil in Huaibei Plain, China. Journal of Groundwater Science and Engineering, 5(3): 213-221.

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SHANG Man-ting, LIU Pei-gui, LEI Chao, et al. 2017: Effect of climate change on the trends of evaporation of phreatic water from bare soil in Huaibei Plain, China. Journal of Groundwater Science and Engineering, 5(3): 213-221.

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Effect of climate change on the trends of evaporation of phreatic water from bare soil in Huaibei Plain, China

1Hefei University of Technology, 230009 Heifei Province, China

Publish Date: 2017-09-28

Abstract

Abstract

When the soil condition and depth to water table stay constant, climate condition will then be the only determinant of evaporation intensity of phreatic water from bare soil. Based on a series of long-term quality-controlled data collected at the Wudaogou Hydrological Experiment Station in the Huaibei Plain, Anhui, China, the variation trends of the evaporation rate of phreatic water from bare soil were studied through the Mann-Kendall trend test and the linear regression trend test, followed by the study on the responses of evaporation to climate change. Results indicated that in the Huaibei Plain during 1991-2008, evaporation of phreatic water from bare soil tended to increase at a rate of 5% on monthly scale in March, June and July while in other months the increase was minor. On the seasonal basis, the evaporation saw significant increase in spring and summer. In addition, annual evaporation tended to grow evidently over time. When air temperature rises by 1 °C, the annual evaporation rate increases by 7.24–14.21%, while when the vapor pressure deficit rises by 10%, it changes from ?0.09 to 5.40%. The study also provides references for further understanding of the trends and responses of regional evapotranspiration to climate change
- Climate change,
- Evaporation of phreatic water from bare soil,
- Fluvo-aquic soil,
- Huaibei Plain,
- Lime concretion black soil

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References(59)

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