Abstract
CFC age and deuterium excess methods were applied to the estimation of groundwater circulation rates in the Quaternary shallow groundwater system of the Henan Plain. The results provide a basis for groundwater renewability evaluation. The spatial distribution of CFC age shows that the groundwater system mainly comprises modern water, less than 50 a. The groundwater of less than 30 a was in the piedmont zone of the Taihang, Funiu, and Dabie Mountains, indicating short groundwater residence times, and fast groundwater cycling, with circulation rates of 27–31 m/d. Groundwater cycling along the Yellow River was also rapid because of exchange with the Yellow River. The circulation rates were 34–54 m/d. In the areas around Tongxu, Shangqiu, Taikang, Xiangcheng, in the middle of the study area, and east of Huaxian-Changyuan and Xixian, Gushi in the south, groundwater age was 30–40 a, suggesting a longer groundwater residence time. The groundwater cycle in these areas was slower than in the piedmonts, and the area along the Yellow River. The circulation rates were 15–26 m/d. In the areas of Luyi, Yongcheng, Zhumadian, Xincai and Huaibin, the groundwater age was older than 40 a, with the longest residence times and slowest circulation rates (∼12 m/d). The correlation between groundwater age and deuterium excess averages for the northern, central, southern shallow groundwater systems and the <30 a, 30–40 a, >40 a groundwater age divisions was strong (R = 0.9714), showing that the groundwater residence time embodied by the deuterium excess parameter was consistent with groundwater age estimated using the CFC method.
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Dong, Wh., Kang, B., Du, Sh. et al. Estimation of shallow groundwater ages and circulation rates in the Henan Plain, China: CFC and deuterium excess methods. Geosci J 17, 479–488 (2013). https://doi.org/10.1007/s12303-013-0037-8
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DOI: https://doi.org/10.1007/s12303-013-0037-8