Redox Transformation of Arsenic by Fe(II)-Activated Goethite (α-FeOOH)

Amstaetter, Katja; Borch, Thomas; Larese-Casanova, Philip; Kappler, Andreas

doi:10.1021/es901274s

Cited by 286 publications

(270 citation statements)

References 52 publications

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“…During data collection, As samples were maintained at a temperature of 5 K to prevent beam-induced redox reactions using an Oxford Instruments CF1208 continuous flow liquid helium cryostat (Oxford Instruments, Abingdon, UK). [58] Energy selection was accomplished with a Si (220) monochromator. All Fe EXAFS spectra were collected in fluorescence mode with a wide-angle collection ionisation chamber (Lytle detector).…”

Section: X-ray Absorption Spectroscopy (Xas)mentioning

confidence: 99%

“…[59] Uranium reference compounds included uranyl acetate and uraninite. [60] Arsenic reference compounds included As III adsorbed to goethite, As V adsorbed to goethite [58] and orpiment (As 2 S 3 ). Standards of arsenic adsorbed to goethite were prepared according to Amstaetter et al by adding 1.2 mg L À1 of sodium arsenite and sodium arsenate to a 5.4 g L À1 suspension of goethite (Bayferrox 920 Z, LANXESS Deutschland GmbH, Leverkusen, Germany).…”

Section: X-ray Absorption Spectroscopy (Xas)mentioning

confidence: 99%

“…Standards of arsenic adsorbed to goethite were prepared according to Amstaetter et al by adding 1.2 mg L À1 of sodium arsenite and sodium arsenate to a 5.4 g L À1 suspension of goethite (Bayferrox 920 Z, LANXESS Deutschland GmbH, Leverkusen, Germany). [58] Orpiment was obtained from the RRUFF database at University of Arizona Mineral Museum and was originally from Mercur, Utah. Linear combination fitting of k 3 -weighted Fe EXAFS spectra was performed from 3 to 12 k (Å À1 ) using Athena.…”

Section: X-ray Absorption Spectroscopy (Xas)mentioning

confidence: 99%

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Effect of biogeochemical redox processes on the fate and transport of As and U at an abandoned uranium mine site: an X-ray absorption spectroscopy study

Troyer

Stone

2014

Environ. Chem.

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Environmental context. Uranium and arsenic, two elements of human health concern, are commonly found at sites of uranium mining, but little is known about processes influencing their environmental behaviour. Here we focus on understanding the chemical and physical processes controlling uranium and arsenic transport at an abandoned uranium mine. We find that the use of sedimentation ponds limits the mobility of uranium; however, pond conditions at our site resulted in arsenic mobilisation. Our findings will help optimise restoration strategies for mine tailings.Abstract. Although As can occur in U ore at concentrations up to 10 wt-%, the fate and transport of both U and As at U mine tailings have not been previously investigated at a watershed scale. The major objective of this study was to determine primary chemical and physical processes contributing to transport of both U and As to a down gradient watershed at an abandoned U mine site in South Dakota. Uranium is primarily transported by erosion at the site, based on decreasing concentrations in sediment with distance from the tailings. Sequential extractions and U X-ray absorption near-edge fine structure (XANES) fitting indicate that U is immobilised in a near-source sedimentation pond both by prevention of sediment transport and by reduction of U VI to U IV . In contrast to U, subsequent release of As to the watershed takes place from the pond partially due to reductive dissolution of Fe oxy(hydr)oxides. However, As is immobilised by adsorption to clays and Fe oxy(hydr)oxides in oxic zones and by formation of As-sulfide mineral phases in anoxic zones down gradient, indicated by sequential extractions and As XANES fitting. This study indicates that As should be considered during restoration of uranium mine sites in order to prevent transport.

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Section: X-ray Absorption Spectroscopy (Xas)mentioning

confidence: 99%

Section: X-ray Absorption Spectroscopy (Xas)mentioning

confidence: 99%

Section: X-ray Absorption Spectroscopy (Xas)mentioning

confidence: 99%

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Effect of biogeochemical redox processes on the fate and transport of As and U at an abandoned uranium mine site: an X-ray absorption spectroscopy study

Troyer

Stone

2014

Environ. Chem.

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“…Green rust was formed under anaerobic conditions with ferrous added. Some part of green rust could transform to goethite after oxidation (Amstaetter et al 2010). Part of hematite could dissolve in WA at first, then the Fe 3?…”

Section: Chemical Fractionation Of Arsenic Using Sequential Extractionsmentioning

confidence: 99%

Evaluation of chemical immobilization treatments for reducing arsenic transport in red mud

Wang

et al. 2013

Environ Earth Sci

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Red mud (RM) was produced during alumina production from bauxite known as the Bayer process. Arsenic was detected in the solid phase of RM (RMsf) which was disposed in the disposal area. This study investigates the effectiveness of using Zero-valent iron (ZVI), ferrihydrite, ferrous sulfate (FeSO 4 ), waste acid (WA) or CO 2 for immobilization of arsenic in the RMsf. To test the effect of the amendments on the arsenic leachability, the RMsf samples were amended with the iron-based materials or acidifiers at various w/w (weight/ weight) ratios (1-10 %) for 30 days. The leachability of arsenic in the RMsf was evaluated by a 4-step water elusion process. After 30-day treatment of the RMsf, the leachability of As decreased from an initial (12.7 %) to (7.0 %) with a w/w ratio of 5 % ZVI (0 %) with 5 % FeSO 4 Á7H 2 O, (3.4 %) with 5 % ferryhydrite, (2.0 %) with 6 % WA and (11.8 %) with 6 % CO 2 . FeSO 4 Á7H 2 O and WA showed more effectively than other amendments for immobilizing arsenic. Arsenic fractionation with a sequential extraction procedure was used to evaluate the arsenic migration potential in the RMsf. FeSO 4 and WA were effective in increasing the hydrous oxide combined arsenic in the RMsf. The leachable Cl -and SO 4 2-in the RMsf increased from 2.9 to 14.1 mg/g and 19.9-44.4 mg/g with 6 % WA and 5 % FeSO 4 Á7H 2 O added, respectively. The estimated cost of the FeSO 4 and WA treatment was 0.47 and 0.49 USD per ton, respectively.

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“…Iron(hydr) oxides could only slightly oxidize As(III), when they were induced or catalyzed, for example, by Fe(II) or light. Early studies showed the rapid oxidation of As(III) to As(V) at the surface of goethite, magnetite and ferrihydrite in Fe(II)-mediated reactions (Amstaetter et al, 2010;Ona-Nguema et al, 2010). It is reported that goethite interacting with dissolved Fe(II) produced the highest redox activity compared with other Fe(III) (oxy)hydroxides (Elsner et al, 2004).…”

Section: Introductionmentioning

confidence: 99%

The fate of arsenic adsorbed on iron oxides in the presence of arsenite-oxidizing bacteria

Zhang

Yin

et al. 2016

Chemosphere

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h i g h l i g h t sMicrobial cells lowered total As adsorption by minerals. Microbial oxidation proceeded much slowly in solid phase than in aqueous phase. Minerals with a higher affinity for As(III), hindered As(III) oxidation more. Under aerobic conditions, As(V) is the primary form in solid and aqueous phases. a b s t r a c t Arsenic (As) is a redox-active metalloid whose toxicity and mobility in soil depend on its oxidation state. Arsenite [As(III)] can be oxidized by microbes and adsorbed by minerals in the soil. However, the combined effects of these abiotic and biotic processes are not well understood. In this study, the fate of arsenic in the presence of an isolated As(III)-oxidizing bacterium (Pseudomonas sp. HN-1, 10 9 colonyforming units (CFUs)$ml À1 ) and three iron oxides (goethite, hematite, and magnetite at 1.6 g L À1 ) was determined using batch experiments. The total As adsorption by iron oxides was lower with bacteria present and was higher with iron oxides alone. The total As adsorption decreased by 78.6%, 36.0% and 79.7% for goethite, hematite and magnetite, respectively, due to the presence of bacteria. As(III) adsorbed on iron oxides could also be oxidized by Pseudomonas sp. HN-1, but the oxidation rate (1.3 mmol h À1 ) was much slower than the rate in the aqueous phase (96.2 mmol h À1 ). Therefore, the results of other studies with minerals only might overestimate the adsorptive capacity of solids in natural systems; the presence of minerals might hinder As(III) oxidation by microbes. Under aerobic conditions, in the presence of iron oxides and As(III)-oxidizing bacteria, arsenic is adsorbed onto iron oxides within the adsorption capacity, and As(V) is the primary form in the solid and aqueous phases. a r t i c l e i n f o

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Redox Transformation of Arsenic by Fe(II)-Activated Goethite (α-FeOOH)

Cited by 286 publications

References 52 publications

Effect of biogeochemical redox processes on the fate and transport of As and U at an abandoned uranium mine site: an X-ray absorption spectroscopy study

Effect of biogeochemical redox processes on the fate and transport of As and U at an abandoned uranium mine site: an X-ray absorption spectroscopy study

Evaluation of chemical immobilization treatments for reducing arsenic transport in red mud

The fate of arsenic adsorbed on iron oxides in the presence of arsenite-oxidizing bacteria

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