Reactive transport model for predicting arsenic transport in groundwater system in Datong Basin
Autor: | Xianjun Xie, Yanxin Wang, Matthew Currell, Qian Yu |
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Rok vydání: | 2018 |
Předmět: |
Hydrology
010504 meteorology & atmospheric sciences Arsenate chemistry.chemical_element Sorption 010501 environmental sciences 01 natural sciences Arsenic contamination of groundwater chemistry.chemical_compound chemistry Geochemistry and Petrology Environmental chemistry Economic Geology Sulfate Dissolution Surface water Geology Arsenic Groundwater 0105 earth and related environmental sciences |
Zdroj: | Journal of Geochemical Exploration. 190:245-252 |
ISSN: | 0375-6742 |
Popis: | High As concentration in groundwater of Datong Basin has emerged as an issue of great concern in the past decade because of its serious impact on the health of many people. The present study is to our knowledge the first attempt model the transport of arsenic in this system using a 1D reactive transport model (PHREEQC). Based on published field data from Shanyin Field Site (Datong Basin), the importance of the (bio)geochemical processes for arsenic mobility is evaluated quantitatively using geochemical models of growing complexity. Arsenic mobility during the surface water and groundwater interactions can be explained by the reductive dissolution of iron oxyhydroxides, sulfate, nitrate and arsenate, and by surface sorption/de-sorption occurring in response to changes in geochemical conditions. Both the Fe(III) surface complexation model and the 1D reactive transport model were employed to depict the arsenic transport in shallow groundwater system during the surface water-groundwater interactions. The surface complexation model results showed that a total of 0.34 mmol and 0.56 mmol arsenic were sorbed onto Fe(III) oxyhydroxides for Well 1-2S and Well 2-2S, respectively, reflecting the important role of surface sorption process on arsenic transport. The 1D model results revealed that redox processes were also critical. The improved calibration of model simulations involving both of these components indicates that the combination of processes is critical to understanding and characterising the transport of arsenic in groundwater during groundwater surface water interaction, especially close to the surface water body. |
Databáze: | OpenAIRE |
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