Genesis of As in the groundwater with extremely high salinity in the Yellow River Delta, China

High arsenic (As) groundwater has been extensively found in river delta worldwide, but understanding of the influence of high salinity on As mobilization remains limited. Therefore, this study took the Yellow River Delta as the study area and tested an alternative method-ionic ratios to explore the hydrogeochemical processes of high As groundwater. Eighty-one groundwater samples and three river water samples were collected for chemical analysis. Based on inflection points of HCO3/Cl, Na/Cl, and SO4/Cl cumulative frequency distribution and hydrogeological conditions, three hydrogeochemical zones have been determined: Weathering-Fresh Water Zone (Zone I), Evaporation-Saline Water Zone (Zone II), and Seawater Mixing-Reduction Zone (Zone III). Concentrations of As and total dissolved solids (TDS) showed an increasing trend in groundwater from Zone I to Zone III. Zone I groundwater with low As and low TDS was mainly controlled by rock weathering and strong flushing. Due to intensive evaporation and seawater mixing, the TDS concentration in the groundwater of Zone II and Zone III increased sharply (up to 145997 mg/L). The high As groundwater in Zone II and Zone III was characterized by high Fe2+ and NH4+ and low NO3- and SO4/Cl, indicating that reductive dissolution of As-bearing iron oxides is the key process for As release. In addition, the significantly positive correlation between As and Cl- (> 10000 mg/L) under different pH conditions indicated that intensive salinization may contribute to As mobility. Results of cluster analysis revealed that reductive dissolution is the principal driving force for As release in coastal groundwater systems and salinization is the secondary one.

Automated summary

This study explored the hydrogeochemical processes of high arsenic groundwater in the Yellow River Delta using the alternative method of ionic ratios. The results indicated that high salinity plays a significant role in the mobilization of arsenic, with reductive dissolution being the principal driving force for arsenic release in coastal groundwater systems.