Alexandra Lightfoot scite author profile

Arsenic groundwater contamination threatens the health of millions of people worldwide, particularly in South and Southeast Asia. In most cases, the release of arsenic from sediment was caused by microbial reductive dissolution of arsenic-bearing iron(III) minerals with organic carbon being used as microbial electron donor. Although in many arsenic-contaminated aquifers high concentrations of methane were observed, its role in arsenic mobilization is unknown. Here, using microcosms experiments and hydrogeochemical and microbial community analyses, we demonstrate that methane functions as electron donor for methanotrophs, triggering the reductive dissolution of arsenic-bearing iron(III) minerals, increasing the abundance of genes related to methane oxidation, and ultimately mobilizing arsenic into the water. Our findings provide evidence for a methane-mediated mechanism for arsenic mobilization that is distinct from previously described pathways. Taking this together with the common presence of methane in arsenic-contaminated aquifers, we suggest that this methane-driven arsenic mobilization may contribute to arsenic contamination of groundwater on a global scale.

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Alexandra Lightfoot

Spatial and temporal evolution of groundwater arsenic contamination in the Red River delta, Vietnam: Interplay of mobilisation and retardation processes

Role of in Situ Natural Organic Matter in Mobilizing As during Microbial Reduction of Fe^III-Mineral-Bearing Aquifer Sediments from Hanoi (Vietnam)

Carbon and methane cycling in arsenic-contaminated aquifers

Noble gas constraints on the fate of arsenic in groundwater

Arsenic mobilization by anaerobic iron-dependent methane oxidation

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Alexandra Lightfoot

Spatial and temporal evolution of groundwater arsenic contamination in the Red River delta, Vietnam: Interplay of mobilisation and retardation processes

Role of in Situ Natural Organic Matter in Mobilizing As during Microbial Reduction of FeIII-Mineral-Bearing Aquifer Sediments from Hanoi (Vietnam)

Carbon and methane cycling in arsenic-contaminated aquifers

Noble gas constraints on the fate of arsenic in groundwater

Arsenic mobilization by anaerobic iron-dependent methane oxidation

Contact Info

Product

Resources

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Role of in Situ Natural Organic Matter in Mobilizing As during Microbial Reduction of Fe^III-Mineral-Bearing Aquifer Sediments from Hanoi (Vietnam)