Origin and Evolution of Saline Spring Water in North and Central Laos Based on Hydrochemistry and Stable Isotopes (δD, δ18O, δ11B, and δ37Cl)

This paper discusses the origin and evolution of saline springs in north and central Laos, based on chemical and stable isotopes (δD, δ18O, δ11B, and δ37Cl). All the saline springs in this study are of the Na–Cl geochemical type. The geochemical and water isotope values suggest that the saline sprin...

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Published inWater (Basel) Vol. 13; no. 24; p. 3568
Main Authors Qin, Xiwei, Ma, Haizhou, Zhang, Xiying, Hu, Xiasong, Li, Guorong, Jiang, Ziwen, Cheng, Huaide, Han, Jibin, Li, Yongshou, Miao, Weiliang, Han, Wenhua, Yang, Sha, Song, Qian, Lei, Shang, Wang, Hongying
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 01.12.2021
Subjects
Basins
Carbonate rocks
Carnallite
Cretaceous
Dissolution
Evaporation
Geochemistry
Geology
Gypsum
Halites
Isotopes
marine evaporites
Meteoric water
Minerals
Mountains
Phase diagrams
Potash
potash exploration prospect
Potassium carbonate
Precipitation
recharge and solute sources
reservoir temperatures
saline springs
Salinity
Salt
Sandstone
Silica
Snowmelt
Spring (season)
Spring water
Stable isotopes
Sutures
Sylvite
Ternary systems
Volcanic rocks
Water springs
United Kingdom
Southeast Asia
Thailand
Laos
China
India
Asia
Indochina
Tibet
Red River
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Summary:This paper discusses the origin and evolution of saline springs in north and central Laos, based on chemical and stable isotopes (δD, δ18O, δ11B, and δ37Cl). All the saline springs in this study are of the Na–Cl geochemical type. The geochemical and water isotope values suggest that the saline springs in this study are mainly derived from meteoric water and/or ice and snow melt from the surrounding mountains and that they also experienced strong evaporation and intense rock–water interactions. The ionic ratios, characteristic coefficients, ternary Ca–SO4–HCO3 phase diagrams, and saturation indices of minerals show that the dissolution of halite, sulfate, and carbonate rocks may be the solute sources for saline springs in this study, whereas the underground brines in the Thakhek potash mining area are geochemically influenced by the dissolution of carnallite and sylvite. The global geothermal δ11B–Cl/B relationship and δ11B values (5.50 to 36.01‰) of saline springs suggest a continental origin of B. This B is most likely derived from marine carbonate rocks and marine evaporates (gypsum and halite) of the late Cretaceous, which is similar to the saline springs of the Nangqen–Qamdo–Simao Salt Basin. The δ37Cl value (−0.12 to +0.79) and the Cl/Br ratio (4076 to 9853) show that dissolution of late cretaceous marine halite layers, atmospheric precipitation, and water–rock interactions between volcanic rocks, mudstones, and sandstone can restrict the δ37Cl values in saline springs. Results from silica geothermometry and multi–mineral equilibrium diagrams indicate that the reservoir temperatures for the saline springs range from 87–137 °C and experience deep circulation. Hydrochemical characteristic coefficients suggest that saline springs in the Muang Say basin may have leached sylvinite and carnallite and that the potash exploration prospect in this area is relatively good.
ISSN:2073-4441
2073-4441
DOI:10.3390/w13243568