Aqueous and solid phase arsenic speciation in the sediments of a contaminated wetland and riverbed

Aqueous and solid phase arsenic speciation in the sediments of a contaminated wetland and riverbed

Mobility of As in the environment is controlled by its association with solid phases through adsorption and co-precipitation. To elucidate the mobilization potential of As deposited in wetland and riverbed sediments of the Wells G & H wetland in Woburn, MA as the result of decades of industrial...

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Published in:Applied geochemistry Vol. 24; no. 2; pp. 346 - 358
Main Authors: Blute, N.K., Jay, J.A., Swartz, C.H., Brabander, D.J., Hemond, H.F.
Format: Journal Article
Language:English
Published: Kidlington Elsevier Ltd 01-02-2009
Elsevier
Subjects:
Earth sciences
Earth, ocean, space
Engineering and environment geology. Geothermics
Exact sciences and technology
Freshwater
Geochemistry
Pollution, environment geology
adsorption
mobility
mobilization
oxides
testing
water table
concentration
aluminum
evapotranspiration
arsenic
extraction
speciation
drill cores
precipitation
wetlands
depressions
depth
solid phase
standard samples
pH
equilibrium
retention
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Summary:Mobility of As in the environment is controlled by its association with solid phases through adsorption and co-precipitation. To elucidate the mobilization potential of As deposited in wetland and riverbed sediments of the Wells G & H wetland in Woburn, MA as the result of decades of industrial activity, As retention mechanisms were inferred from aqueous and solid phase geochemical measurements of sediment cores. Testing included a sequential extraction method designed for and standard-tested with As phases and pE/pH equilibrium modeling. The uppermost sediments in the Wells G & H wetland contain elevated concentrations of both dissolved and solid phase As (up to 2,000 μg/L and 15,000 μg/g, respectively) and a maximum concentration between 30 and 40 cm depth. Measurements obtained in this study suggested that As in the wetland sediments was predominantly adsorbed, likely onto amorphous Fe (hydr)oxide phases and mixed valence Fe phases. In the riverbed sediments, however, a relatively greater proportion of the solid As was associated with more reduced and crystalline phases, and adsorbed As was more likely associated with Al oxide or secondary reduced Fe phases. pH–pe modeling of the Fe–As–S system was consistent with observations. The association of As with more oxidized phases in the wetland compared with the riverbed sediments may result from a combination of plant activities, including evapotranspiration-driven water table depression and/or root oxygenation.
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ISSN:0883-2927
1872-9134
DOI:10.1016/j.apgeochem.2008.10.012