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Volume 11 Issue 2
Jun.  2023
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Article Contents
Meng RF, Yang HF, Bao XL, et al. 2023. Optimizing groundwater recharge plan in North China Plain to repair shallow groundwater depression zone, China. Journal of Groundwater Science and Engineering, 11(2): 133-145 doi:  10.26599/JGSE.2023.9280012
Citation: Meng RF, Yang HF, Bao XL, et al. 2023. Optimizing groundwater recharge plan in North China Plain to repair shallow groundwater depression zone, China. Journal of Groundwater Science and Engineering, 11(2): 133-145 doi:  10.26599/JGSE.2023.9280012

Optimizing groundwater recharge plan in North China Plain to repair shallow groundwater depression zone, China

doi: 10.26599/JGSE.2023.9280012
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  • Corresponding author: yanghuifeng@mail.cgs.gov.cn
  • Received Date: 2022-06-15
  • Accepted Date: 2022-11-20
  • Available Online: 2023-04-20
  • Publish Date: 2023-06-30
  • The North China Plain is one of the main grain producing areas in China. However, over-exploitation has long been unsustainable since the water supply is mainly from groundwater. Since 2014, the South-to-North Water Diversion Project’s central route has been charted to the integrated management of water supply and over-exploitation, which has alleviated the problem to a certain extent. Although the Ministry of Water Resources has made many efforts on groundwater recharge since 2018 most of which have been successful, the recharge has not yet been sufficiently focused on the repair of shallow groundwater depression zones. It still needs further optimization. This paper discusses this particular issue, proposes optimized recharge plan and provides the following recommendations: (1) Seven priority target areas are selected for groundwater recharge in alluvial and proluvial fans in the piedmont plain, and the storage capacity is estimated to be 181.00×108 m3; (2) A recharge of 31.18×108 m3/a is required by 2035 to achieve the repair target; (3) It is proposed to increase the recharge of Hutuo River, Dasha River and Tanghe River to 19.00×108 m3/a and to rehabilitate Gaoliqing-Ningbailong Depression Zone; increase the recharge of Fuyang River, Zhanghe River and Anyang River to 7.05×108 m3/a and rehabilitate Handan Feixiang-Guangping Depression Zone; increase the recharge of Luanhe River by 0.56×108 m3/a and restore Tanghai Depression Zone and Luanan-Leting Depression Zone; moderately reduce the amount of water recharged to North Canal and Yongding River to prevent excessive rebound of groundwater; (4) Recharge through well is implemented on a pilot basis in areas of severe urban ground subsidence and coastal saltwater intrusion; (5) An early warning mechanism for groundwater quality risks in recharge areas is established to ensure the safety. The numerical groundwater flow model also proves reasonable groundwater level restoration in the depression zones by 2035.
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  • Auckenthaler A, Baenninger D, Zechner E, et al. 2010. Drinking water production close to contaminant sites: A case study from the region of Basel, Switzerland. IAHS Publication, 342: 167−170.
    Azizur RM, Rernd R, Gogu RC, et al. 2012. A new spatial multi-criteria decision support tool for site selection for implementation of managed aquifer recharge. Journal of Environmental Management, 99: 61−75. DOI: 10.1016/j.jenvman.2012.01.003.
    Bouwer H. 2002. Artificial recharge of groundwater: Hydrogeology and engineering. Hydrogeology Journal, 10: 121−142. DOI: 10.1007/s10040-001-0182-4.
    Chen F, Ding YY, Tang SN, et al. 2021. Practice and effect analysis of river-lake ecological water supplement and groundwater recharge in the North China region. China Water Resources, 07: 36−39. (in Chinese)
    Cui X, Zhang B, He MX, et al. 2021. Impacts of ecological water replenishment on the hydrochemical characteristics of surface water and groundwater in Lake Baiyangdian Watershed. Journal of Lake Sciences, 33(06): 1675−1686. (in Chinese) DOI: 10.18307/2021.0606.
    Dillon PJ. 2004. Future management of aquifer recharge. Hydrogeology Journal, 13(1): 313−316. DOI: 10.1007/s10040-004-0413-6.
    Ghayoumian J, Ghermezcheshme B, Feizinia S, et al. 2005. Integrating GIS and DSS for identification of suitable for artificial recharge, case study Meimeh Basin, Isfahan, Iran. Environmental Geology, 47: 493−500. DOI: 10.1007/s00254-004-1169-y.
    He YP, Li SJ, Li Y, et al. 2019. Effect of South-to-North water transfer project on recharge and water level in Chaobai river area. Beijing Water, 03: 21−26. (in Chinese) DOI: 10.19671/j.1673-4637.2019.03.006.
    Hendricks FHJ, Kaiser HP, Kuhlmann U, et al. 2011. Operational real-time modeling with ensemble Kalman filter of variably saturated subsurface flow including stream-aquifer interaction and parameter updating. Water Resources Research, 47 (2): W02532.
    Hu LT, Guo JL, Zhang SQ, et al. 2020. Response of groundwater regime to ecological water replenishment of the Yongding River. Hydrogeology & Engineering Geology, 47(05): 5−11. (in Chinese) DOI: 10.16030/j.cnki.issn.1000-3665.202008027.
    Huo LT, Wang BX, Pan ZH, et al. 2020. Environmental impact by surface-water recharge of groundwater in Beijing Mihuaishun replenishment area-correspondence analysis. Journal of Beijing Normal University (Natural Science), 56(02): 195−203. (in Chinese) DOI: 10.12202/j.0476-0301.2020058.
    Jia WF, Yang Y, Zhao Y, et al. 2016. Simulation of the water-rock reaction in Chaobai River ground-water storage area. South-to-North Water Transfers and Water Science & Technology, 14(01): 143−148, 135. (in Chinese) DOI: 10.13476/j.cnki.nsbdqk.2016.01.024.
    Li HT, Shi P, Wu HX. 2008. Artificial recharge technology of groundwater. Natural Resource Economics of China, (03): 41−42, 45, 48. (in Chinese)
    Li WP, Wang LF, Yang HF, et al. 2020. The groundwater over-exploitation status and countermeasure suggestions of the North China Plain. China Water Resources, 13: 26−30. (in Chinese)
    Lin XY. 1984. On development and utilization of groundwater reservoir. Journal of Jilin University (Earth Science Edition), 02: 113−121. (in Chinese)
    Liu LC, Zheng FD, Li BH, et al. 2015. Experiment of groundwater quality change for simulating the South-to-North water into the Mihuaishun aquifer. Hydrogeology & Engineering Geology, 42(04): 18−22, 55. (in Chinese) DOI: 10.16030/j.cnki.issn.1000-3665.2015.04.04.
    Moeck C, Radny D, Borer P, et al. 2016. Multicomponent statistical analysis to identify flow and transport processes in a highly-complex environment. Journal of Hydrology, 542: 437−449. DOI: 10.1016/j.jhydrol.2016.09.023.
    Sarfaraz A, Annesh B, Sujith R, et al. 2021. Managed aquifer recharge implementation criteria to achieve water sustainability. Science of the Total Environment, 768: 1−19. DOI: 10.1016/J.SCITOTENV.2021.144992.
    Shi JS, Li GM, Liang X, et al. 2014. Evolution mechanism and control of groundwater in the North China Plain. Acta Geoscientica Sinica, 35(5): 527−534. (in Chinese) DOI: 10.3975/cagsb.2014.05.01.
    Sprenger C, Hartog N, Hernández M, et al. 2017. Inventory of managed aquifer recharge sites in Europe: Historical development, current situation and perspectives. Hydrogeology Journal, 25: 1909−1922. DOI: 10.1007/s10040-017-1554-8.
    Tian MZ, Zhao L, Cui WJ, et al. 2022. Control and influence of rising groundwater level on land under the background of South-to-North Water Diversion: A case study of Chaobai River groundwater system in Beijing. Geology in China. (in Chinese)
    Tian X, Meng SH, Cui XX, et al. 2021. Hydrochemical Effect of groundwater recharge in over-exploited area of Hutuo River Basin. Research of Environmental Sciences, 34(03): 629−636. (in Chinese) DOI: 10.13198/j.issn.1001-6929.2020.07.19.
    Wang Z, Fu Y, Zhu JS, et al. 2021. Effect assessment on groundwater recharge for typical rivers in North China. Journal of Jilin University (Earth Science Edition), 51(03): 843−853. (in Chinese) DOI: 10.13278/j.cnki.jjuese.20200078.
    Xiao Y, Shan R, Li S, et al. 2017. Change in groundwater resource and environment of South-to-North water recharge area of Chaobai River. Beijing Water, (04): 5−8. (in Chinese) DOI: 10.19671/j.1673-4637.2017.04.002.
    Yang HF, Cao WG, Zhi CS, et al. 2021. Evolution of groundwater level in the North China Plain in the past 40 years and suggestions on its overexploitation treatment. Geology in China, 48(04): 1142−1155. (in Chinese) DOI: 10.12029/gc20210411.
    Yang HF, Meng RF, Bao XL, et al. 2022. Assessment of water level threshold for groundwater restoration and over-exploitation remediation the Beijing-Tianjin-Hebei Plain. Journal of Groundwater Science and Engineering, 10(02): 113−127.
    Yu Y, Qi TL. 2020. Analysis on the effect of comprehensive control pilot project of groundwater supplement for groundwater over-abstraction in Northern China. Haihe Water Resources, (03): 7−9,16. (in Chinese) DOI: 10.3969/j.issn.1004-7328.2020.03.003.
    Zhang GH, Fei YH, Liu KY, et al. 2007. Groundwater potential recovery and water level variation in the Shijiazhuang water-receiving area at the central line of the south-to-north water transfer project. Geological Bulletin of China, 144(05): 583−589. (in Chinese)
    Zhang GH, Lian YL, Liu CH, et al. 2011. Situation and origin of water resources in short supply in North China Plain. Journal of Earth Sciences and Environment, 33(2): 172−176. (in Chinese)
    Zhang ZJ, Fei YH, Chen ZY, et al. 2009. Investigation and Evaluation of Sustainable Utilization of Groundwater in North China Plain. Beijing: Geological publishing house. (in Chinese)
    Zheng FD, Liu LC, Yang MQ, et al. 2012. Simulation of water-rock interaction in the injection of water from the South-to-North Diversion Project to the aquifer in the western suburb of Beijing. Hydrogeology & Engineering Geology, 39(06): 22−28. (in Chinese) DOI: 10.16030/j.cnki.issn.1000-3665.2012.06.005.
    Zhu JY, Guo HP, Li WP, et al. 2014. Relationship between land subsidence and deep groundwater yield in the North China Plain. South-to-North Water Transfers and Water Science & Technology, 12(3): 165−169. (in Chinese) DOI: 10.13476/j.cnki.nsbdqk.2014.03.036.
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