• ISSN 2305-7068
  • Indexed by ESCI CABI CAS
  • DOAJ EBSCO Scopus GeoRef AJ CNKI
Advanced Search
Volume 3 Issue 1
Mar.  2015
Turn off MathJax
Article Contents
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.
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.

Analysis of evaporation of high-salinity phreatic water at a burial depth of 0 m in an arid area

  • Publish Date: 2015-03-28
  • High-salinity phreatic water refers to which with total dissolved solids (TDS)>30 g/L. Previous studies have shown that high salinity phreatic water evaporation is different at different depths. High salinity phreatic water evaporation under 0 m depth is the basis of the high salinity phreatic water evaporation studies. In this study, evaporation of high-salinity phreatic water at a burial depth of 0 m in arid area was investigated. New insights were gained on evaporation mechanisms via experiments conducted on high-salinity phreatic water with TDS of 100 g/L at 0 m at the study site at Changji Groundwater Balance Experiment Site, Xinjiang Uygur Autonomous Region in China, where the lithology of the vadose (unsaturated zone) was silty clay. Comparison was made on the data of high-salinity phreatic water evaporation, water surface evaporation (EΦ20) and meteorological data obtained in two complete hydrological years from April 1, 2012 to March 31, 2014. The experiments demon?strated that when the lithology of the vadose zone is silty clay, the burial depth is 0 m and the TDS is 100 g/L, intra-annual variation of phreatic water evaporation is the opposite to the variation of atmospheric evaporation EΦ20 and air temperature. The salt crust formed by the evaporation of high-salinity phreatic water has a strong inhibitory effect on phreatic water evaporation. Large volumes of precipitation can reduce such an inhibitory effect. During freezing periods, surface snow cover can promote the evaporation of high-salinity phreatic water at 0 m; the thicker the snow cover, the more apparent this effect is.
  • 加载中
  • 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.
  • Relative Articles

    [1] Man Li, Wei Zhang, Yu-zhong Liao, Feng Liu, Long Li, 2025: Evaluation of the scaling and corrosion in Tai'an geothermal water , Journal of Groundwater Science and Engineering.  doi: 10.26599/JGSE.2025.9280044
    [2] Li-juan Wang, Zhe Wang, Gao-lei Jiang, Zhen-long Nie, Jian-mei Shen, Sheng-hua Song, 2024: Variations in evaporation from water surfaces along the margins of the Badain Jaran Desert over nearly 60 years and influencing factors, Journal of Groundwater Science and Engineering, 12, 253-263.  doi: 10.26599/JGSE.2024.9280019
    [3] Yousef Al-Abed Allah Malik, Omar Abu Abbas Mohammad, 2023: Experimental investigation of the impact of water depth, inlet water temperature, and fins on the productivity of a Pyramid Solar Still, Journal of Groundwater Science and Engineering, 11, 183-190.  doi: 10.26599/JGSE.2023.9280016
    [4] Khan Tanzeel, Akhtar Malik Muhammad, Malghani Gohram, Akhtar Rabia, 2022: Comparative analysis of bacterial contamination in tap and groundwater: A case study on water quality of Quetta City, an arid zone in Pakistan, Journal of Groundwater Science and Engineering, 10, 153-165.  doi: 10.19637/j.cnki.2305-7068.2022.02.005
    [5] Li-sha MA, Zhan-tao HAN, Yan-yan WANG, 2021: Dispersion performance of nanoparticles in water, Journal of Groundwater Science and Engineering, 9, 37-44.  doi: 10.19637/j.cnki.2305-7068.2021.01.004
    [6] Xiao-lin YIN, Yuan-yuan GAO, Hai-ping WU, Xue-ming ZHAO, 2020: Water-saving potential evaluation of water-receiving regions in Shandong province on the East Route of the South-to-North Water Transfer Project of China, Journal of Groundwater Science and Engineering, 8, 287-297.  doi: 10.19637/j.cnki.2305-7068.2020.03.009
    [7] Prusty Rabiranjan, Biswal Trinath, 2020: Physico-chemical, bacteriological and health hazard effect analysis of the water in Taladanda Canal, Paradip area, Odisha, India, Journal of Groundwater Science and Engineering, 8, 338-348.  doi: 10.19637/j.cnki.2305-7068.2020.04.004
    [8] CHEN Peng, CHEN Kang, GAO Ye-xin, 2018: Analysis of phreatic evaporation law and influence factors of typical lithology in Hebei Plain, Journal of Groundwater Science and Engineering, 6, 270-279.  doi: 10.19637/j.cnki.2305-7068.2018.04.003
    [9] SHANG Man-ting, LIU Pei-gui, LEI Chao, LIU Ming-chao, WU Liang, 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, 213-221.
    [10] HAO Qi-chen, SHAO Jing-li, CUI Ya-li, ZHANG Qiu-lan, 2016: Development of a new method for efficiently calculating of evaporation from the phreatic aquifer in variably saturated flow modeling, Journal of Groundwater Science and Engineering, 4, 26-34.
    [11] WANG Ying, CHEN Zong-yu, 2016: Responses of groundwater system to water development in northern China, Journal of Groundwater Science and Engineering, 4, 69-80.
    [12] WANG Hong-ke, GUO Jiao, SHI Ying-chun, 2015: Type of major water hazards and study of countermeasures in Shennan Mining Area, Journal of Groundwater Science and Engineering, 3, 70-76.
    [13] GONG Xiao-ping, JIANG Guang-hui, CHEN Chang-jie, GUO Xiao-jiao, ZHANG Hua-sheng, 2015: Specific yield of phreatic variation zone in karst aquifer with the method of water level analysis, Journal of Groundwater Science and Engineering, 3, 192-201.
    [14] ZHOU Li-ling, CHENG Zhe, DUAN Lei, WANG Wen-ke, 2015: Distribution of groundwater salinity and formation mechanism of fresh groundwater in an arid desert transition zone, Journal of Groundwater Science and Engineering, 3, 268-279.
    [15] HAN Kang-qin, LIU Jian, HAN Lei-lei, HAN Wen-ling, ZHANG Yun-xiao, 2014: Prediction of Impacts Caused by South-to-North Water Diversion on Underground Water Level in Shijiazhuang, Journal of Groundwater Science and Engineering, 2, 27-33.
    [16] LIU Kai, SUN Ying,  LI Yu, LIU Jiu-rong, LIU Ying-chao, 2014: Zonation for exploitation and utilization of geothermal water in Beijing, Journal of Groundwater Science and Engineering, 2, 94-104.
    [17] Le SONG, Yan-pei CHENG, 2014: Optimization Research of Water-Soil Resources in Huanghua, Journal of Groundwater Science and Engineering, 2, 86-94.
    [18] GE Li-qiang, CHENG Yan-pei, YUE Chen, 2014: Study of water resources for crop utilization in China from the perspective of Virtual Water, Journal of Groundwater Science and Engineering, 2, 67-75.
    [19] Cheng Yanpei, Ma Renhui, 2013: Analysis of Water Resource Demands: Based on the Hydrological Unit, Journal of Groundwater Science and Engineering, 1, 48-59.
    [20] Do Van Binh, 2013: Source and Formation of the Arsenic in Ground Water in Hanoi , Vietnam, Journal of Groundwater Science and Engineering, 1, 102-108.
  • 加载中

Catalog

    Article Metrics

    Article views (611) PDF downloads(993) Cited by()
    Proportional views
    Related

    JGSE-ScholarOne Manuscript Launched on June 1, 2024.

    Online Submission

    /

    DownLoad:  Full-Size Img  PowerPoint
    Return
    Return