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Journal of Arid Land  2023, Vol. 15 Issue (9): 1037-1051    DOI: 10.1007/s40333-023-0067-7     CSTR: 32276.14.s40333-023-0067-7
Research article     
Evolution of groundwater recharge-discharge balance in the Turpan Basin of China during 1959-2021
QIN Guoqiang, WU Bin*(), DONG Xinguang, DU Mingliang, WANG Bo
College of Hydraulic and Civil Engineering, Xinjiang Agricultural University, Urumqi 830052, China
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Abstract  

Groundwater overexploitation is a serious problem in the Turpan Basin, Xinjiang Uygur Autonomous Region of China, causing groundwater level declines and ecological and environmental problems such as the desiccation of karez wells and the shrinkage of lakes. Based on historical groundwater data and field survey data from 1959 to 2021, we comprehensively studied the evolution of groundwater recharge and discharge terms in the Turpan Basin using the groundwater equilibrium method, mathematical statistics, and GIS spatial analysis. The reasons for groundwater overexploitation were also discussed. The results indicated that groundwater recharge increased from 14.58×108 m3 in 1959 to 15.69×108 m3 in 1980, then continued to decrease to 6.77×108 m3 in 2021. Groundwater discharge increased from 14.49×108 m3 in 1959 to 16.02×108 m3 in 1989, while continued to decrease to 9.97×108 m3 in 2021. Since 1980, groundwater recharge-discharge balance has been broken, the decrease rate of groundwater recharge exceeded that of groundwater discharge and groundwater recharge was always lower than groundwater discharge, showing in a negative equilibrium, which caused the continuous decrease in groundwater level in the Turpan Basin. From 1980 to 2002, groundwater overexploitation increased rapidly, peaking from 2003 to 2011 with an average overexploitation rate of 4.79×108 m3/a; then, it slowed slightly from 2012 to 2021, and the cumulative groundwater overexploitation was 99.21×108 m3 during 1980-2021. This research can provide a scientific foundation for the restoration and sustainable use of groundwater in the overexploited areas of the Turpan Basin.



Key wordsgroundwater overexploitation      groundwater recharge      groundwater discharge      climate change      human activities      Turpan Basin     
Received: 20 July 2023      Published: 30 September 2023
Corresponding Authors: * WU Bin (E-mail: WUBINxjnydx@126.com)
Cite this article:

QIN Guoqiang, WU Bin, DONG Xinguang, DU Mingliang, WANG Bo. Evolution of groundwater recharge-discharge balance in the Turpan Basin of China during 1959-2021. Journal of Arid Land, 2023, 15(9): 1037-1051.

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http://jal.xjegi.com/10.1007/s40333-023-0067-7     OR     http://jal.xjegi.com/Y2023/V15/I9/1037

Fig. 1 Overview of the Turpan Basin and the location of the study area. DEM, digital elevation model.
Fig. 2 Evolution of seven groundwater recharge terms in the Turpan Basin during 1959-2021. QMFLIR, mountain front's lateral infiltration recharge; QLRFR, latent river flow recharge; QRIR, river infiltration recharge; QCLR, canal leakage recharge; QFIR, field infiltration recharge; QRPSR, reservoir and pond seepage recharge; QRETURN, recharge terms of groundwater transformation.
Year Groundwater recharge (×108 m3/a) Groundwater discharge (×108 m3/a)
QMFLIR QLRFR QRIR QCLR QFIR QRPSR QRETURN Total QE QR QK QMW QS QAW Total
1959 1.62 0.69 3.67 2.11 0.77 0.02 5.70 14.58 5.16 0.71 5.78 0.01 2.83 0.00 14.49
1989 1.66 0.55 3.04 2.38 1.12 0.09 6.37 15.20 3.72 0.57 3.70 4.88 2.68 0.47 16.02
2003 1.60 0.40 2.47 1.80 0.95 0.14 4.50 11.86 3.30 0.35 2.70 6.40 1.96 0.26 14.97
2011 1.62 0.27 2.25 1.51 0.67 0.14 3.21 9.66 2.37 0.28 1.35 8.28 1.57 0.09 13.95
2021 1.63 0.13 2.08 1.02 0.35 0.07 1.48 6.77 1.47 0.00 0.91 6.71 0.88 0.00 9.97
Table 1 Groundwater recharge and discharge data in the Turpan Basin in the five periods of 1959, 1989, 2003, 2011, and 2021
Fig. 3 Evolution of the number of karez wells and the amount of karez well outflow (QK) in the Turpan Basin during 1959-2021
Fig. 4 Evolution of the number of mechanical wells and the amount of mechanical well extraction (QMW) in the Turpan Basin during 1959-2021
Fig. 5 Evolution of groundwater discharge terms in the Turpan Basin during 1959-2021. QAW, artesian well outflow; QS, spring overflow; QR, river discharge; QE; evapotranspiration.
Fig. 6 Evolution of groundwater recharge and discharge in the Turpan Basin during 1959-2021
Period End of period Average
overexploitation
(×108 m3/a)
Cumulative overexploitation
(×108 m3)
Recharge
(×108 m3/a)
Discharge
(×108 m3/a)
Overexploitation
(×108 m3/a)
1959 14.58 14.49 - - -
1960-1970 15.56 15.22 - - -
1970-1980 15.69 15.66 - - -
1980-1989 15.20 16.02 0.82 0.36 3.21
1989-2003 11.86 14.97 3.11 1.40 19.57
2003-2011 9.66 13.95 4.29 4.79 38.35
2011-2021 6.77 9.97 3.20 4.23 38.08
Total 99.21
Table 2 Calculation of groundwater overexploitation in the Turpan Basin during 1959-2021
Fig. 7 Spatial distribution of cumulative groundwater level decline in the Turpan Basin during 1980-2021. (a), 1980-1989; (b), 1989-2003; (c), 2003-2011; (d), 2011-2021.
Period Average annual groundwater storage variables (×108 m3/a) Cumulative groundwater storage variables (×108 m3)
1980-1989 0.43 3.90
1989-2003 1.53 21.40
2003-2011 4.81 38.54
2011-2021 3.82 38.23
Sum 2.49 102.10
Table 3 Groundwater storage variables in the Turpan Basin during 1980-2021
[1]   Abdisalam J, Shi Y H. 2015. Research on the groundwater resources condition at Turpan Region. China Rural Water and Hydropower, (11): 55-58, 64. (in Chinese)
[2]   Adhikari R K, Yilmaz A G, Mainali B, et al. 2022. Methods of groundwater recharge estimation under climate change: A review. Sustainability, 14(23): 15619, doi: 10.3390/su142315619.
doi: 10.3390/su142315619
[3]   Alanur A, Tursun K, Mahpirat N, et al. 2019. A comparison on characteristics of temperature and precipitation in Turpan City and Hami City. Journal of Northwest Normal University (Natural Science), 55(3): 105-111, 134. (in Chinese)
[4]   Amini A, Hesami A. 2017. The role of land use change on the sustainability of groundwater resources in the eastern plains of Kurdistan, Iran. Environmental Monitoring and Assessment, 189: 297, doi: 10.1007/s10661-017-6014-3.
doi: 10.1007/s10661-017-6014-3 pmid: 28551886
[5]   Cha J, Lee J Y, Chia R W. 2023. Microplastics contamination and characteristics of agricultural groundwater in Haean Basin of Korea. Science of The Total Environment, 864: 161027, doi: 10.1016/j.scitotenv.2022.161027.
doi: 10.1016/j.scitotenv.2022.161027
[6]   Chen F, Ding Y Y, Li Y Y, et al. 2020a. Practice and consideration of groundwater overdraft management in North China. South to North Water Transfers and Water Science & Technology, 18(2): 191-198. (in Chinese)
[7]   Chen F, Xu X Y, Yang Y, et al. 2020b. Analysis of evolutionary trends and influencing factors of groundwater resources in China. Advance in Water Science, 31(6): 811-819. (in Chinese)
[8]   Chen H R, Wu M S, Duan Z, et al. 2023. Forecasting the human and climate impacts on groundwater resources in the irrigated agricultural region of North China Plain. Hydrological Processes, 37(3): e14853, doi: 10.1002/hyp.14853.
doi: 10.1002/hyp.14853
[9]   Chen L. 2014. The study of regional hydrogeological conditions and groundwater circulation in Turpan Basin. PhD Dissertation. Beijing: China University of Geosciences. (in Chinese)
[10]   Chen Q. 1998. Annual and flood season variation characteristics of surface runoff in northern mountainous area of Turpan Basin. Bimonthly of Xinjiang Meteorology, (5): 36-39. (in Chinese)
[11]   Cui H, Wang R, Zhang M Y, et al. 1990. Research Report on Groundwater Resources and Rational Development and Utilization in the Turpan Basin. Urumqi: The First Brigade of Hydrogeology, Xinjiang Bureau Geo-exploration & Mineral Development, 76-77. (in Chinese)
[12]   Deng M J. 2010. Kariz wells in arid land and mountain-front depressed ground reservoir. Advances in Water Science, 21(6): 748-756. (in Chinese)
[13]   Dong X G, Deng M J. 2005. Groundwater Resources in Xinjiang. Urumqi: Xinjiang Science and Technology Press, 92-106. (in Chinese)
[14]   Duque C, Rosenberry D O. 2022. Advances in the study and understanding of groundwater discharge to surface water. Water, 14(11): 1698, doi: 10.3390/w14111698.
doi: 10.3390/w14111698
[15]   Feng H M, Zhang G H, Wang D L. 2014. Analysis of the driving forces of groundwater flow field evolution in Shijiazhuang area in the past 50 years. Journal of Hydraulic Engineering, 45(2): 180-186. (in Chinese)
[16]   Huang D Q, Cui J, Li C Z. 1990. Report on the Comprehensive Evaluation of Water Resources in the Turpan Basin, Xinjiang 1/200,000. Urumqi: The First Brigade of Hydrogeology, Xinjiang Bureau Geo-exploration & Mineral Development, 77-79. (in Chinese)
[17]   Keranmu A, Abudushalike N. 2014. Analysis of temperature and rainfall changes in recent 52 years in Turpan city, Xinjiang. Journal of Arid Land Resources and Environment, 28(12): 45-50. (in Chinese)
[18]   Kronvang B, Wendland F, Kovar K. 2020. Land use and water quality. Water, 12(9): 2412, doi: 10.3390/w12092412.
doi: 10.3390/w12092412
[19]   Le Brocque A F, Kath J, Reardon-Smith K. 2018. Chronic groundwater decline: A multi-decadal analysis of groundwater trends under extreme climate cycles. Journal of Hydrology, 561: 976-986.
doi: 10.1016/j.jhydrol.2018.04.059
[20]   Li F L, Chen H W, Wang K R, et al. 2018. A review of research on groundwater-supported ecosystems. Advance in Water Science, 29(5): 750-758. (in Chinese)
[21]   Li J, Zhou Y X, Wang W K, et al. 2022a. Response of hydrogeological processes in a regional groundwater system to environmental changes: A modeling study of Yinchuan Basin, China. Journal of Hydrology, 615: 128619, doi: 10.1016/j.jhydrol.2022.128619.
doi: 10.1016/j.jhydrol.2022.128619
[22]   Li Y F, Wang H L, Sun B. 1963. Hydrogeological Conditions and Water Resources Development and Utilization in the Turpan Basin, Xinjiang. Urumqi: The First Brigade of Hydrogeology, Xinjiang Bureau Geo-exploration & Mineral Development, 41-43. (in Chinese)
[23]   Li Y T, Friedman N, Teatini P, et al. 2022b. Sensitivity analysis of factors controlling earth fissures due to excessive groundwater pumping. Stochastic Environmental Research and Risk Assessment, 36(11): 3911-3928.
doi: 10.1007/s00477-022-02237-8
[24]   Li Y Y, Cao J T, Shen F X. 2014. Changes in renewable water resources in China from 1956 to 2010. Scientia Sinica (Terrae), 44(9): 2030-2038. (in Chinese)
[25]   Ma J Z, Li J J, Gao Q Z. 2002. Groundwater evolution and its influence on eco-environment under climatic change and human activity in the south of Tarim Basin. Arid Land Geography, 25(1): 16-23. (in Chinese)
[26]   Mao H R, Wang G C, Liao F. 2022. Geochemical evolution of groundwater under the influence of human activities: A case study in the southwest of Poyang Lake Basin. Applied Geochemistry, 140: 105299, doi: 10.1016/j.apgeochem.2022.105299.
doi: 10.1016/j.apgeochem.2022.105299
[27]   Mohallel S A, Gomaa M A. 2017. Studying the impacts of groundwater evolution on the environment, west Qena City, Egypt. Arabian Journal of Geosciences, 10(16): 372, doi: 10.1007/s12517-017-3151-5.
doi: 10.1007/s12517-017-3151-5
[28]   Pradeep G, Krishan G. 2022. Groundwater and agriculture potential mapping of Mewat District, Haryana, India. Discover Water, 2: 11, doi: 10.1007/s43832-022-00019-5.
doi: 10.1007/s43832-022-00019-5
[29]   Qin G Q, Ling J S, Chen M, et al. 2021. The Evolution of Underground Water Resources in the Plain Area of Tuha Basin in the Past 60 Years and Its Trend Analysis. Urumqi: Xinjiang Water Resources and Hydropower Survey Design and Research Institute Co., Ltd., 268-269. (in Chinese)
[30]   Ren D Y, Xu X, Huang Q Z, et al. 2018. Analyzing the role of shallow groundwater systems in the water use of different land-use types in arid irrigated regions. Water, 10(5): 634, doi: 10.3390/w10050634.
doi: 10.3390/w10050634
[31]   Ren Z X, Yang D Y. 2007. Impacts of climate change on agriculture in the arid region of northwest China in resent 50 years. Journal of Arid Land Resources and Environment, 21(8): 48-53. (in Chinese)
[32]   Scanlon B R, Reedy R C, Gates J B. 2010. Impact of agroecosystems on groundwater resources in the Central High Plains, USA. Agricultural, Ecosystem & Environment, 139(4): 700-713.
[33]   Secci D, Tanda M G, D'Oria M D, et al. 2022. Impacts of climate change on groundwater droughts by means of standardized indices and regional climate models. Journal of Hydrology, 603: 127154, doi: 10.1016/j.jhydrol.2021.127154.
doi: 10.1016/j.jhydrol.2021.127154
[34]   Shang S S, Lian L S, Ma T, et al. 2018. Spatiotemporal variation of temperature and precipitation in northwest China in recent 54 years. Arid Zone Research, 35(1): 68-76. (in Chinese)
[35]   Shang Z, Tang Y, Yang S S. 2020. Analysis of groundwater dynamic characteristics and influencing factors in Turpan basin in recent 30 years. Journal of China Institute of Water Resources and Hydropower Research, 18(3): 192-203. (in Chinese)
[36]   Sheng Z P. 2013. Impacts of groundwater pumping and climate variability on groundwater availability in the Rio Grande Basin. Ecosphere, 4(1): 1-25.
[37]   Shi J S, Li G M, Liang X. 2014. Mechanism and regulation of groundwater evolution in the North China Plain. Acta Geoscientica Sinica, 35(5): 527-534. (in Chinese)
[38]   Su H C, Wei W S, Han P. 2003. Changes in air temperature and evaporation in Xinjiang during recent 50 years. Journal of Glaciology and Geocryology, 25(2): 174-178. (in Chinese)
[39]   Sun Q Y, Guo H, Lu C Y. 2021. Current status and development trend of groundwater dynamic evolution research. Journal of Irrigation and Drainage, 40(S1): 58-64. (in Chinese)
[40]   Trásy-Havril T, Szkolnikovics-Simon S, Mádl-Szőnyi J. 2022. How complex groundwater flow systems respond to climate change induced recharge reduction. Water, 14(19): 3026, doi: 10.3390/w14193026.
doi: 10.3390/w14193026
[41]   Wang L S, Yue L L, Tang Z J, et al. 2014. Influence of climate change and agricultural development on groundwater level in Shiyang river basin. Transactions of the Chinese Society for Agricultural Machinery, 45(1): 121-128. (in Chinese)
[42]   Wang S J, Zhang S M, Deng M J, et al. 2010. Complete Book of Rivers and Lakes in Xinjiang, China. Beijing: China Water Resources and Hydropower Press, 223-224. (in Chinese)
[43]   Wang Y X, Li X. 1997. Studies on sustainable utilization of water resources in the Turpan basin. Journal of Arid Land Resources and Environment, 11(3): 9-14. (in Chinese)
[44]   Warku F, Korme T, Wedajo G K. 2022. Impacts of land use/cover change and climate variability on groundwater recharge for upper Gibe watershed, Ethiopia. Sustainable Water Resources Management, 8(1): 19-34.
doi: 10.1007/s40899-022-00607-2
[45]   Wei Y, Wang F, Hong B, et al. 2023. Revealing spatial variability of groundwater level in typical ecosystems of the Tarim Basin through ensemble algorithms and limited observations. Journal of Hydrology, 620: 129399, doi: 10.1016/j.jhydrol.2023.129399.
doi: 10.1016/j.jhydrol.2023.129399
[46]   Wu B, Du M L, Yang P N. 2016. Evolution of groundwater recharge and discharge in Shanshan County in the last 60 years in relation to the attenuation of flow in the karez well. Transactions of the Chinese Society of Agricultural Engineering, 32(16): 102-108. (in Chinese)
[47]   Wu B, Du M L, Mu Z X, et al. 2021. Analysis on the variation of groundwater resources and influencing factors in Xinjiang plain area from 1956 to 2016. Advances in Water Science, 32(5): 659-669. (in Chinese)
[48]   Yang S M, Chu X Z, Zhang Y. 2018. Analysis on characteristics of temperature and precipitation change in Turpan city in recent 65 years. Ecological Science, 37(3): 44-50. (in Chinese)
[49]   Ye Y X, Du L J, Zhang B Z, et al. 2014. Analysis on feature of climate and runoff evolution in Turpan and its surrounding areas. Journal of Water Resources & Water Engineering, 25(6): 61-67. (in Chinese)
[50]   Yoshihisa U. 2004. Final Report of the Project on Sustainable Study of Groundwater Resources in the Turpan Basin, Xinjiang, People's Republic of China. Tokyo: Nippon Kokusai Kaisha Co., 352-367. (in Chinese)
[51]   Zhang J Y, Wang G Q, Jin J L, et al. 2020. Evolution and variation characteristics of the recorded runoff for the major rivers in China during 1956-2018. Advances in Water Science, 31(2): 153-161. (in Chinese)
[52]   Zhang M J, Liu J, Xie N. 2013. Report on Groundwater Exploration in the Turpan Basin, Xinjiang. Urumqi: The First Brigade of Hydrogeology, Xinjiang Bureau Geo-exploration & Mineral Development, 56-57. (in Chinese)
[53]   Zhou W B, Shi J L, Yang L H. 2007. Groundwater Utilization. Beijing: China Water Resources and Hydropower Press, 67-71. (in Chinese)
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