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Volume 7 Issue 3
Sep.  2019
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Article Contents
XU Jun-xiang, WANG Shao-juan, LI Chang-suo, et al. 2019: Numerical analysis and evaluation of groundwater recession in a flood detention basin. Journal of Groundwater Science and Engineering, 7(3): 253-263. doi: DOI: 10.19637/j.cnki.2305-7068.2019.03.006
Citation: XU Jun-xiang, WANG Shao-juan, LI Chang-suo, et al. 2019: Numerical analysis and evaluation of groundwater recession in a flood detention basin. Journal of Groundwater Science and Engineering, 7(3): 253-263. doi: DOI: 10.19637/j.cnki.2305-7068.2019.03.006

Numerical analysis and evaluation of groundwater recession in a flood detention basin

doi: DOI: 10.19637/j.cnki.2305-7068.2019.03.006
  • This study analyzes the groundwater environment in the Yangzhuang flood detention basin in Henan Province, China. A numerical model of groundwater flow is established based on the hydrogeological conditions in the basin and changes of groundwater level in the flood detention basin under flood detention and recession conditions. The results show that during flood diversion and storage, the groundwater level in the basin rises, mainly in four flood detention zones, with a maximum rise of 1.0 m. After the floodwater recedes, the groundwater level slowly drops in the detention basin along with flood discharge, finally returning to its original level fifty days later. This study indicates that groundwater recession in the flood detention basin is a slow process, where the rise of groundwater level may cause environmental problems such as soil swamping.
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  • WANG Zhong-hao. 2015. Study on the long-term stability of tunnel-type anchorage surrounded by soft rock after reservoir water level rising. Wuhan: The Yangtse River Scientific Research Institute.
    ZHENG Jing-wei. 2005. Exploring the rational mode of flood control and disaster reduction, flood resource utilization, economic development and ecological restoration in Dahuangpuwa detention basin. China Institute of Water Resources and Hydropower Research.
    WEN Guang-chao, WANG Wen-ke, et al. 2018. Quantitatively evaluating relationship be-tween river water and groundwater in Bayin River of northwest China using hydrochemistry and stable isotope. Arid Land Geography, 41(4): 734-743.
    Hsieh P A, Neuman S P, et al. 1985. Field determination of the three-dimensional hy-draulic conductivity tensor of anisotropic media: 1. Theory. Water Resources Research, 21(11): 1655-1665.
    XING Xu-guang, SHI Wen-juan, WANG Quan-jiu. 2013. Discussion of E0 value in common groundwater evaporation empirical models. Agriculture Research in the Arid Area, 31(4): 57-60.
    LI Xi-meng. 2014. Groundwater numerical simulation of the middle reaches of Heihe River Basin. Beijing: Tsinghua University.
    Boufadel M C, Peridier V. 2002. Exact analytical expressions for the piezometric profile and water exchange between stream and groundwater during and after a uniform rise of the stream level. Water Resources Research, 38(7): 27-1-27-6.
    WANG Wei, LI Chuan-qi. 2004. Function, value and multi-purpose utilization of flood detention basins. Water Resources Development Research, 09: 26-28.
    JIANG Hai-ning, GU Hong-biao, et al. 2016. Interaction relationship between surface water and groundwater in Zhaosu-Tekes Basin, Xinjiang Uygur Autonomous Region, China. Arid Land Geography, 39(5): 1078-1088.
    ZHANG Hong-ren. 1993. A comparative study of numerical solution of PDE in geosciences. Acta Geologica Sinica: 31-52.
    WANG Xiao-lei. 2013. Study on numerical modeling of flood propagation and flood loss assessment of flood detention basin. Baoding: Agricultural University of Hebei Province.
    Scanlon B R, Mace R E, et al. 2003. Can we simulate regional groundwater flow in a karst system using equivalent porous media models? Case study, Barton Springs Edwards aquifer, USA. Journal of Hydrology, 276(1-4): 137-158.
    XUE Yu-qun, WU Ji-chun. 2010. Groundwater dynamics (3rd edition). Beijing: Geology Press: 31-52.
    QIN Da-jun, ZHAO Zhan-feng, et al. 2017. Using hydrochemical, stable isotope, and river water recharge data to identify groundwater flow paths in a deeply buried karst system. Hydrological Processes, 31(24): 4297-4314.
    Edjah Adwoba, Stenni Barbara, et al. 2017. Characterization of surface water and groundwater quality in the Lower Tano River Basin using statistical and isotopic approach. EGU General Assembly Con-ference. EGU General Assembly Con-ference Abstracts.
    CUI Ya-li, SHAO Jing-li, LI Ci-jun. 2001. Relation of transform between surface water and ground water in Manasi River valley. Hydrogeology & Engineering Geology, 28(2): 9-13.
    JI Lei. 2016. Using stable hydrogen and oxygen isotope research the conversion relationship of surface water and groundwater in Manas River Basin. Shihezi: Shihezi University.
    Mikhail F, Vladimir B, et al. 2016. Site selection for flood detention basins with minimum environmental impact. Procedia Engineering, 165: 1629-1636.
    YE Ren-yuan. 2015. Interaction of surface water and groundwater in Yili-Gongnaisi River valley. Xi’an: Changan University.
    Vieira I, Barreto V, et al. 2018. The use of detention basins to reduce flash flood hazard in small and steep volcanic watersheds-a simulation from Madeira Island. Journal of Flood Risk Management, 11(S2): 930-942.
    Hantush M M. 2005. Modeling stream-aquifer interactions with linear response functions. Journal of Hydrology, 311(1-4): 59-79.
    LIN Jie. 2016. Study on ecological governance of river and flood detention area of Xiaoqing River. Jinan: Shandong University.
    FENG Ping, MAO Hui-hui, YU Ping. 2011. Analysis of risk and benefit of flood uti-lization of detention basin. Journal of Na-tural Disasters, (06): 99-103.
    Hunt B. 2005. Bank-storage problem and the dupuit approximation. Journal of Hydrologic Engineering, 10(2): 118-124.
    LIU Qiang, QIN Yi, et al. 2015. A coupled 1D-2D hydrodynamic model for flood simulation in flood detention basin. Natural Hazards, 75(2): 1303-1325.
    WANG Jing. 2017. Study of simulation of flood routing in Pangtoupao flood detention basin based on EFDC. Dalian: Dalian University of Technology.
    HU Jian. 2005. The research of fast assessment and compensation in exertion loss of store floodwater area. Nanjing: Hohai University.
    Nuremanguli?Tuersun. 2012. Effect of ecological water transportation on groundwater changes and populous euphratica growth of the lower reaches of Tarim River. Urumqi: Xinjiang University.
    CHEN Ya-ning, LI Wei-hong, et al. 2003. The influence of groundwater on vegetation in the lower reaches of Tarim River, China. Acta Geographica Sinia, 58(4): 542-549.
    QI Ke, HE Xi-long, ZHANG Peng. 2014. Risk zone partition and application of flood detention basin in Huaihe River. Zhi Huai,10: 16-17.
    GUO Feng-qing, ZENG Hui, et al. 2013. Risk analysis and research on evacuation to relocate flood detention area in Pajiang River. Journal of Catastrophology, 03: 85-90.
    Hsieh P A, Neuman S P, et al. 1985. Field de-termination of the three-dimensional hy-draulic conductivity Tensor of Anisotropic Media: 2. Methodology and Application to Fractured Rocks. Water Resources Research, 21(11):1655-1665.
    XU Zhong-ping, ZHOU Xun, et al. 2018. Research advances of numerical simulation of ground?water in karst areas. Carslogica Sinica, 37(4): 475-483.
    Hantush M M, Harada M, Marino M A. 2002. Hydraulics of stream flow routing with bank storage. Journal of Hydrologic Engineering, 76(1-2): 76-89.
    ZHANG Xiao-shuai, CHENG Xiang-long. 2013. Analysis of the calculation method of the flood routing process. Journal of Shandong Agricultural University (Natural Science), 44 (3): 385-390.
    DUAN Yang, LIAO Wei-hong, et al. 2014. Numerical simulation of in flood routing detention basin based on EFDC model. South-to-North Water Transfers and Water Science & Technology, 12(5): 160-165.
    WANG Xiao-ning. 2007. The impact of detention basin operation to region social-economic development. Beijing: Beijing University of Technology.
    MA Zhi-ren. 2006. Current status and characteristics of flood detention basins in China and abroad. Heilongjiang Science and Technology of Water Conservancy, 34(06): 90-91.
    XU Hai-liang, YE Mao, et al. 2007. Ecological-economic values of the natural vegetation restoration after groundwater elevation at the lower reaches of the Tarim River. Arid land geography, 30(4): 482-486.
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