| Citation: | WANG Ying, CHEN Zong-yu. 2016: Responses of groundwater system to water development in northern China. Journal of Groundwater Science and Engineering, 4(2): 69-80.
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The increased demands on water resources in northern China have had a significant impact on groundwater systems in the last three to four decades, including reductions in groundwater recharge capacity and overall water quality. These changes limit the potential for groundwater uses in this area. This paper discusses the issues surrounding groundwater system use in the eight basins of northern China as water resources have been developed. The results demonstrate that the recharge zone has shifted from the piedmont to the agricultural area, and that the total recharge rate in the basins tended to decrease. This decrease in arid inland basins was mainly caused by both the excessive use of water in the watershed area and irrigated channel anti-seepage. In semi-arid basins, the decrease observed in the groundwater recharge rate is related to an overall reduction in precipitation and increasing river impoundment. In addition, intensive exploitation of groundwater resources has resulted in disturbances to the groundwater flow regime in arid and semi-arid inland basins. Arid inland basins demonstrated fast falling groundwater levels in the piedmont plains resulting in declines of spring flow rates and movement of spring sites to lower locations. In the semi-arid basins, i.e. the North China Plain and the Song-nen Plain, groundwater depression cones developed and intersected regional groundwater flow. The semi-arid basins of the North China Plain and the Song-nen Plain have experienced significant hydrochemical evolution of groundwater characterized by changing water type including increase of TDS and pollutants.
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Treidel H, Martin-Bordes J J, Gurdak J J. 2011. Climate change effects on groundwater resources: A global synthesis of findings and recommendations. Boca Raton, Leiden: CRC Press.
|
|
ZHANG Zong-hu, LI Lie-rong, et al. 2004. Groundwater resources of China. Beijing: Sinomaps Press, 211–215.
|
|
CHENG Xu-xue, CHEN Chong-xi, et al. 2009. Investigation and assessment of groundwater resources rational exploitation and utilization in the Shule River Basin of the Hexi Corridor. Beijing: The Geological Publishing House, 27–143.
|
|
Green T R, Taniguchi M, et al. 2011. Beneath the surface of global change: Impacts of climate change on groundwater. Journal of Hydrology, 405(3–4): 532-560.
|
|
MA Zong-jin, GAO Qing-hua. 2004. Climate changes of China in the Quaternary period and analysis on drought disasters of North China in the future. Quaternary Sciences, 24(3): 245–251.
|
|
HAN Ying, YAN Shi-long, et al. 2009. Investigation and assessment of groundwater resources and their environmental problems in the six basins of Shanxi Province. Beijing: The Geological Publishing House, 71-3340.
|
|
LI Zhi, YU Meng-wen, et al. 2009. Investigation and assessment of groundwater resources and their related environmental issues in the west Liaohe Plain. Beijing: The Geological Publishing House, 62-208.
|
|
ZHAO Hai-qing, ZHAO Yong-sheng, et al. 2009. Investigation and assessment of groundwater resources and their related environmental problems in the Songnen Plain. Beijing: The Geological Publishing House, 24–125.
|
|
ZHANG He-sheng. 2005. A brief introduction of the changes in groundwater resources in the Hexi Corridor. Hydrogeology and Engineering Geology, (4): 81–83.
|
|
CHEN Zong-yu, NIE Zhen-long, et al. 2006. Environmental isotopic study on the recharge and residence time of groundwater in the Heihe River Basin, northwestern China. Hydrogeology Journal, 14(8): 1635–1651.
|
|
Currell M J, HAN D M, et al. 2012. Sustainability of groundwater usage in northern China: dependence on palaeowaters and effects on water quality, quantity and ecosystem health. Hydrological Processes, 26(26): 4050–4066.
|
|
Puri S. 2006. Global change, its impact on functions of aquifer systems and their dependent ecosystems. In: Groundwater and Ecosystems. Netherlands: Springer, 289–293.
|
|
CHEN Meng-xiong. 1995. Impacts of human activities on the hydrological regime and ecosystems in an arid area of northwest China. In: Proceedings of a Boulder Symposium. Paris: IAHS Publ, (230): 113–139.
|
|
SHI Ya-feng, SHEN Yong-ping, et al. 2003. Discussion on the present climate change from warm-dry to warm-wet in northwest China. Quaternary Sciences, 23(2): 152–164.
|
|
WU Xue-hua, QIAN Hui, et al. 2009. Investigation and assessment of rational allocation of groundwater resources in the Yinchuan Plain. Beijing: The Geological Publishing House.
|
|
Scanlon B R, Reed R C, et al. 2005. Impact of land use and land cover change on groundwater recharge and quality in the southwestern US. Global Change Biology, 11(10): 1577–1593.
|
|
Taniguchi M, Holman I P. 2010. Groundwater response to changing climate. Boca Raton, Leiden: CRC Press, 232.
|
|
CHEN Tian-de, CHEN Xu-guang, et al. 2009. Investigation and assessment of groundwater resources and its environmental issues in the Junggar Basin. Beijing: The Geological Publishing House, 10–330.
|
|
QIAN H, LI P, et al. 2012. Assessment of groundwater vulnerability in the Yinchuan Plain, northwest China using OREADIC. Environmental Monitoring and Assessment, 184(6): 3613–3628.
|
|
CHEN Zong-yu, WANG Ying, et al. 2010. Groundwater changes of the selected groundwater systems in northern China in recent fifty years. Quaternary Sciences, 30(1): 115–126.
|
|
ZHANG Zhao-ji, FEI Yu-hong, et al. 2009. Investigation and assessment of sustainable utilization of groundwater resources in the north China Plain. Beijing: The Geological Publishing House, 40–470.
|
|
CHEN Zong-yu, WEI Wen, et al. 2011. Identifying the recharge sources and age of groundwater in the Songnen Plain (northeast China) using environmental isotopes. Hydrogeology Journal, 19(1): 163–176.
|
|
Gurdak J J, Hanson R T, et al. 2007. Climate variability controls on unsaturated water and chemical movement, high plains aquifer, USA. Vadose Zone Journal, 6(3): 533–547.
|
|
WANG Yong-gui, GUO Hong-ye, et al. 2009. Investigation and assessment of groundwater resources and their environmental issues in the Qaidam Basin. Beijing: The Geological Publishing House, 66–312.
|
|
CHEN Meng-xiong, MA Feng-shan. 2002. Groundwater resources and environment in China. Beijing: Seismological Press, 481.
|
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