Citation: | JIA Rui-liang, ZHOU Jin-long, LI Qiao, et al. 2015: Analysis of evaporation of high-salinity phreatic water at a burial depth of 0 m in an arid area. Journal of Groundwater Science and Engineering, 3(1): 1-8. |
ZHOU Jin-long, et al. 2002. Experiment on the transforming relationship of atmospheric precipitation, irrigation water and soil water and groundwater water in plain area of Xinjiang. Urumqi: Xinjiang Sci-Tech and Public Health Press, 57-65.
|
FU Qiu-ping, ZHANG Liang-hui, WANG Quan- jiu, et al. 2007. Impact of Eo value on calculation accuracy of phreatic evaporation empirical formulae. Arid Land Geography, 30(6):820-825.
|
HU Shu-jun, SONG Yu-dong, TIAN Chang-yan, et al. 2005. Relationship between water surface evaporation and phreatic water evaporation when phreatic water buried depth is zero for different soil in Tarim River basin. Transactions of the Chinese Society Agri-cultural Engineering, 21(S1):80-83.
|
ZHANG Jiang-guo, XU Xin-wen, LEI Jia-qiang, et al. 2010. Effects of salt crust on soil evaporation condition with saline-water drip- irrigation in extreme arid region. Transactions of the Chinese Society Agricultural Engineering, 26(9):34-39.
|
ZHANG Jiang-guo, SUN Shu-guo, XU Xin-wen, et al. 2010. Chemical characteristics and its effect on soil evaporation of soil salt crusts in the Tarim desert highway shelterbelts. Journal of Arid Land Resources and Environment, 24(4):174-179.
|
LI Xian-wen, ZHOU Jin-long,JIN Meng-gui, et al. 2012. Experiment on evaporation of high- TDS phreatic water in arid area. Journal of Water Resources & Water Engineering, 23(5): 6-10.
|
LI Xian-wen, ZHOU Jin-long, JIN Meng-gui, et al. 2012. Soil-water characteristic curves of high-TDS and suitability of fitting models. Transactions of the Chinese Society Agri-cultural Engineering, 28(13): 135-141.
|
Editorial Board of the Physical Geography of China of the Chinese Academy of Sciences. 1981. The physical geography of China- groundwater. Beijing: Science Press, 69, 72-75.
|
LEI Zhi-dong, SHANG Song-hao, YANG Shi-xiu, et al. 1999. Simulation on phreatic eva-poration during soil freezing. Journal of Hydraulic Engineering, 30(6):6-10.
|
WU Feng-chun, YANG Yu-ying. 1991. The dis-cussiones on the freezing-point depression. Journal of Inner Mongolia Teachers Uni?versity (Natural Science Edition), 8(3):55-58.
|
JIA Rui-liang, ZHOU Jin-long, GAO Ye-xin, et al. 2015. Preliminary analysis on evaporation rules of high-salinity phreatic water in arid area. Advances in Water Science, 26(1):44-50.
|
MA Hong, HU Ru-ji. 1995. Effects of snow cover on thermal regime of frozen soil. Arid Land Geography, 18(4):23-27.
|
XING Xu-guang, SHI Wen-juan, WANG Quan-jiu. 2013. Discussion on E0 value in common groundwater evaporation empirical models. Agricultural Research in the Arid Areas, 31(4):57-60.
|
SHAO Ming-an, WANG Quan-jiu, HUANG Ming- fu. 2006. Soil physics. Beijing: Higher Edu-cation Press, 63-64.
|
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