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Environmental Earth Sciences
Published in: Environmental Earth Sciences 5/2014

01-03-2014 | Original Article

Modeling freshening time and hydrochemical evolution of groundwater in coastal aquifers of Shenzhen, China

Authors: Kouping Chen, Jiu Jimmy Jiao

Published in: Environmental Earth Sciences | Issue 5/2014

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Abstract

This work investigated the freshening time and hydrochemical evolution of coastal groundwater in two brackish aquifers in Shenzhen, China. One was the brackish aquifer that resulted from heavy pumping, and the other was the aquifer reclaimed from the coastal sea. Freshening time and hydrochemical evolution of brackish aquifers were quantitatively evaluated using PHREEQC 2.0, a one-dimensional reactive-transport model. Freshening time was shown to mainly depend on pore water velocity, while the chemical composition of groundwater was determined by the cation exchange capacity of the aquifer. It was shown that after heavy pumping ceased, the freshening time for the original coastal aquifer ranged from 20 to over 80 years. While for the coastal reclaimed aquifer, the freshening time was from 85 to 140 years, which depended on the hydraulic conductivity of the fill materials in the reclaimed site. During aquifer freshening, groundwater evolved from Na–Cl type to Ca–Mg–HCO3 or Na–HCO3 type. A sensitivity analysis showed that the freshening time was most sensitive to the pore water velocity in the aquifer, while the groundwater chemical composition was most sensitive to the values of cation exchange capacity of the aquifer. As for the dispersivity, it had almost no effect on the freshening time and the chemical composition of groundwater.
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Metadata
Title
Modeling freshening time and hydrochemical evolution of groundwater in coastal aquifers of Shenzhen, China
Authors
Kouping Chen
Jiu Jimmy Jiao
Publication date
01-03-2014
Publisher
Springer Berlin Heidelberg
Published in
Environmental Earth Sciences / Issue 5/2014
Print ISSN: 1866-6280
Electronic ISSN: 1866-6299
DOI
https://doi.org/10.1007/s12665-013-2641-3

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