Using hydrochemical and stable isotopic (δ2H, δ18O, δ11B, and δ37Cl) data to understand groundwater evolution in an unconsolidated aquifer system in the southern coastal area of Laizhou Bay, China

This study illustrates the origin of Quaternary brines and groundwater salinization processes at Laizhou Bay using hydrochemical and δ2H, δ18O, δ11B and δ37Cl data. The characteristics of the major ionic components of these brines demonstrated that brines originated from evaporated seawater. The δ2H...

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Bibliographic Details
Published in:Applied geochemistry 2018-03, Vol.90, p.129-141
Main Authors: He, Zekang, Ma, Chuanming, Zhou, Aiguo, Qi, Huihui, Liu, Cunfu, Cai, Hesheng, Zhu, Huichao
Format: Article
Language:English
Subjects:
Ion filtration
Quaternary brines
Southern plain of Laizhou Bay
δ11B
δ2H and δ18O
δ37Cl
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Summary:This study illustrates the origin of Quaternary brines and groundwater salinization processes at Laizhou Bay using hydrochemical and δ2H, δ18O, δ11B and δ37Cl data. The characteristics of the major ionic components of these brines demonstrated that brines originated from evaporated seawater. The δ2H and δ18O values of brines showed that seawater underwent strong evaporation and that these brines underwent mixing with paleo-meteoric water or surface water. The fact that the Cl/Br mass ratios of the Laizhou Bay brines (180–291) are lower than that of halite dissolution brine (>1000) contradicts the hypothesis that these brines were derived from halite dissolution, and the fact that the δ37Cl values (0.14‰–0.21‰) of these brines are more enriched than those derived from seawater evaporation represents positive evidence that evaporated seawater in the lagoon infiltrated through clay layer, during which ion filtration resulted in the positive Cl isotopic compositions of these brines. The higher B isotopic compositions (49.88‰–64.42‰) and lower B/Cl molar ratios (8.5 × 10–5∼1.6 × 10–4) of these brines are consistent with the brine origin determined based on the analysis of Cl isotopes. As the evaporated water infiltrated the clay layer, the preferential adsorption of 10B onto clay dominated the B isotopic composition of the brine. Five different mixing processes were calculated using B contents and B isotopic compositions. These calculations illustrated that one shallow saline groundwater (No. 05) was derived from the mixing of fresh groundwater and deep brine, thus indicating that brine intrusion occurred in the northern area of Changyi, which was caused by the over-exploitation of fresh groundwater. While one shallow saline groundwater (No. 10) and one deep saline groundwater (No. 12) in the northern of Xiaying were derived from the mixing of brine and seawater. The δ11B values of the two shallow brackish groundwater samples were close to that produced by the desorption of B from marine clay, and their B/Cl molar ratios were relatively higher, which demonstrated that B-desorption dominated the characteristic B hydrochemical compositions of brackish groundwater. •δ11B with δ37Cl in unconsolidated aquifer was surveyed for the first time.•δ37Cl and δ11B show brine originated form evaporation, filtration, not halite dissolution.•Brine mixed with paleo-meteoric or fresh surface water indicated by δ2H and δ11B.•B and B isotope show brine intrusion and the mixing of
ISSN:0883-2927
1872-9134
DOI:10.1016/j.apgeochem.2018.01.003