Isotopic Stratification and Its Implications in Groundwater of Northern China

Zongyu Chen; Guanghui Zhang; Zhenlong Ni; Jixiang Qi; Yunju Nan

Sep 2001

Article Contents

Journal of Earth Science > 2001 > 12(3): 249-257.

Zongyu Chen, Guanghui Zhang, Zhenlong Ni, Jixiang Qi, Yunju Nan. Isotopic Stratification and Its Implications in Groundwater of Northern China. Journal of Earth Science, 2001, 12(3): 249-257.

Citation:

Zongyu Chen, Guanghui Zhang, Zhenlong Ni, Jixiang Qi, Yunju Nan. Isotopic Stratification and Its Implications in Groundwater of Northern China. Journal of Earth Science, 2001, 12(3): 249-257.

Zongyu Chen, Guanghui Zhang, Zhenlong Ni, Jixiang Qi, Yunju Nan. Isotopic Stratification and Its Implications in Groundwater of Northern China. Journal of Earth Science, 2001, 12(3): 249-257.

Citation:

Zongyu Chen, Guanghui Zhang, Zhenlong Ni, Jixiang Qi, Yunju Nan. Isotopic Stratification and Its Implications in Groundwater of Northern China. Journal of Earth Science, 2001, 12(3): 249-257.

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Isotopic Stratification and Its Implications in Groundwater of Northern China

1.
Institute of Hydrogeology and Env ironmental Geology, Chinese Academy of Geological Sciences, Shijiaz huang 050061
2.
College of Earth Sciences, Jilin University, Changchun 130026

Funds:

the National Natural Science Foundation of China 49871079

Received Date: 15 Apr 2001
Accepted Date: 30 Aug 2001

Abstract

Abstract

The contents of D, ⁸O, ³H and ¹⁴C, distinctive in shallow and deep Quaternary aquifers beneath northern China, reflect differences in average paleoclimatic conditions between the Holocene and the last glacial period in Pleistocene.Groundwater in deep confined aquifer was recharged during the last glacial period.The depletions of δ(D) and δ(¹⁸O) of this water, 4×10^-3-16×10^-3 and 1×10^-3-2×10^-3 when compared with the shallow water recharged in Holocene, suggest that the annual mean temperature was lower in the last glacial period than that in the Holocene.The continental gradient of D and ¹⁸O found in old groundwater is essentially similar to that in Holocene, suggesting that the atmospheric circulation did not undergo substantial changes over northern China for the past 30 000 years in spite of the changes in the temperature.Groundwater isotopic stratification indicates three different recharge mechanisms and the influence of modern hydrological circulation, which are very important for the understanding of the continental hydrological circulation and the sustainable development of groundwater resources.
- isotopes, aquifers,
- paleoclimate and paleohydrology,
- recharge mechanism,
- sustainable development,
- northern China

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References(41)

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