Identification of Hydro-Geochemical Processes in Groundwater by Using Major Ion Chemistry: A Case Study

Lin Hua Sun

doi:10.4028/www.scientific.net/AMR.726-731.3424

Paper Titles

Evaluation of TRMM Summer Precipitation over Huai-River Basin in China
p.3401

Groundwater Quality Evaluation of Beihai, Gunangxi Beibu Gulf Economic Zone
p.3407

Hydraulic Characteristic Analysis of Three Gorges Reservoir Xiangxi Bay
p.3413

Hydrochemical Characteristics and Evolution Laws of Groundwater in Ligezhuang Area, Qingdao
p.3419

Identification of Hydro-Geochemical Processes in Groundwater by Using Major Ion Chemistry: A Case Study
p.3424

Influence of the Scheduling of the Three Gorges Reservoir on the Hydrodynamic Field in Xiangxi River
p.3429

Influence of Tidal Gate on Hydrodynamic and Sedimentary Environment
p.3434

Model Study of the Water Exchange in a Shallow Bay
p.3439

Numerical Investigation of the Upper Ocean Response to the Typhoon Winnie (1997) Using an Air-Sea Coupled Model
p.3443

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Identification of Hydro-Geochemical Processes in Groundwater by Using Major Ion Chemistry: A Case Study

Abstract:

Hydro-geochemistry is important for water disaster controlling as it can be used for either understanding of hydrological evolution or water source discrimination. Groundwater samples from the sandstone aquifer in Xutuan coal mine, northern Anhui Province, China have been collected for major ion chemical analysis to understand the operating mechanism of geochemical processes for variation of groundwater chemistry, which will be useful for improving the understanding of hydro-chemical systems in coal mine. The results suggest that they are medium to slightly (6.8 to 8.64 with an average of 7.61) with high concentration of total dissolved solids (943 and 1362 mg/L with mean of 1171 mg/L)). Most of the groundwater samples are classified as Na- HCO₃-Cl and Na-Cl- HCO₃ types according to their relative concentrations of cations and anions. Correlation between ion concentrations, as well as principle component analysis imply that dissolution of dolomite, halite, gypsum, silicate weathering and ion exchange are responsible for the chemical variations of the groundwater.