XAS Evidence of As(V) Association with Iron Oxyhydroxides in a Contaminated Soil at a Former Arsenical Pesticide Processing Plant

Cancès, Benjamin; Juillot, Farid; Morin, Guillaume; Laperche, Valérie; Álvarez, Lauro Vladimir Valle; Proux, Olivier; Hazemann, Jean‐Louis; Brown, Gordon E.; Calas, Georges

doi:10.1021/es050920n

Cited by 127 publications

(117 citation statements)

References 33 publications

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“…The same is true for the two samples from the Datong Basin of Shanxi in China , which were also collected from different depths. The results are consistent with those of numerous reports citing stronger sorption of As(V) than As(III) in minerals and soils at the concentration ranges typical of natural systems (Belzile and Tessier, 1990;Goldberg, 2002;Hering, 2003, 2006;Cancès et al, 2005;Ackermann et al, 2008;Tufano and Fendorf, 2008); this is specifically true at pH < 7. At higher pH values, the extent of As(III) and As(V) adsorption is more similar (Sharma and Sohn, 2009).…”

Section: Sorption and Conversion Of Inorganic Arsenic Speciessupporting

confidence: 92%

“…Nevertheless, the reduction of sorbed As(V) results in the mobilization of the more mobile and bioavailable As(III), which is also more (twice to three times) toxic than As(V) compounds (Vaughan, 2006). Iron oxides play a pivotal role in the biogeochemical behavior of As, and provide an ubiquitous As-trapping pool in soils and sediments (Belzile and Tessier, 1990;Cancès et al, 2005;Ackermann et al, 2008). Hydrous ferric oxides (e.g., ferrihydrite) are the most reactive soil components with respect to As sorption and can take up hundreds of mg/kg As, either as As(III) or As(V) (Goldberg, 2002 neutral to alkaline pH (i.e., closer to the pK a of H 3 AsO 3 at 9.2), arsenate and arsenite both adsorb with similar efficiency onto the surfaces of hydrous ferric oxides and crystalline Fe oxides via the formation of strong inner-sphere surface complexes (Morin and Calas, 2006).…”

Section: Introductionmentioning

confidence: 99%

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Conversion, sorption, and transport of arsenic species in geological media

Sun

Gao

et al. 2012

Applied Geochemistry

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a b s t r a c tThis work addresses the inter-conversion and sorption of inorganic As species in representative geological media. Through the sensitive quantification of As(III) and As(V) with liquid chromatography-inductively coupled plasma-mass spectrometry, and through integrated batch and column approaches, it is shown that natural media can either reduce or oxidize As species. Oxidation of As(III) to As(V) is shown in the Hanford sediment, while reduction of As(V) to As(III) is shown for the surface soil of Savannah River Site. Overall, the sorption distribution coefficient of As(V) onto geological media is much larger than that of As(III), and a reduction of the more sorptive As(V) to As(III) will lead to groundwater enrichment with As. Coupled with the different sorption behavior of As(III) and As(V), the inter-conversion of these species will strongly affect the geochemical cycling of redox-sensitive As in the subsurface.

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Section: Sorption and Conversion Of Inorganic Arsenic Speciessupporting

confidence: 92%

Section: Introductionmentioning

confidence: 99%

Conversion, sorption, and transport of arsenic species in geological media

Sun

Gao

et al. 2012

Applied Geochemistry

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“…This is followed by studies of increasingly complex model systems, using both UHV and in situ methods, ultimately approaching the complexity of natural systems (e.g., Templeton et al, 2001;Fandeur et al ., 2009;Ona-Nguema et al, 2009;Ha et al ., 2009Ha et al ., , 2010Lee et al, 2010;Wang et al ., submitted-a) . In order to assure that the model systems chosen for study are relevant to the naturally occurring phenomena we wish to understand, parallel field studies of real environmental samples (e.g ., soils polluted with arsenic or lead) are also essential (e.g., Foster et al, 1998;Morin et al, 1999;Cancès et al ., 2005) . To illustrate this approach, we present a number of examples of experimental and theoretical studies of mineral-water interface reactions in model systems of increasing complexity as well as in real environmental systems .…”

Section: The Nature Of Solid-water Interfacesmentioning

confidence: 99%

“…Although not as well publicised, there are also many examples of As-contaminated soils and sediments in other areas that impact humans . Some of the well-studied areas include the Mother Lode Gold District of the Sierra Nevada foothills, California (Foster et al ., 1998), a natural As geochemical anomaly in central France (Morin et al ., 2002), a former industrial plant in central France (Cancès et al, 2005), an acid mine drainage (AMD) system in southern France , and the naturally polluted aquifer sediments in the Ganges Delta, Bangladesh introduced above . All of these As pollution problems are impacted by sorption/desorption…”

Section: Arsenic-polluted Soils and Groundwater Aquifersmentioning

confidence: 99%

Mineral-Aqueous Solution Interfaces and Their Impact on the Environment

Brown¹,

Calas²

2012

GeochemPersp

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“…Conversely, secondary arsenate compounds comprise a large class of minerals that have been found in many oxidized environments, e.g., soils, mine tailings, and former industrial sites, and among them, mimetite [Pb 5 (AsO 4 ) 3 Cl] and schultenite (PbHAsO 4 ) are probably the most common (20,21). From the end of the 19th century, lead arsenates, e.g., schultenite, were employed for decades as insecticides in agriculture, increasing the concentration of arsenic in soils (20,22,23). Schultenite is a very rare mineral but is very stable in acidic solutions (20,21,24).…”

mentioning

confidence: 99%

Fungal Bioweathering of Mimetite and a General Geomycological Model for Lead Apatite Mineral Biotransformations

Ceci

Kierans

Hillier

et al. 2015

Appl Environ Microbiol

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f Fungi play important roles in biogeochemical processes such as organic matter decomposition, bioweathering of minerals and rocks, and metal transformations and therefore influence elemental cycles for essential and potentially toxic elements, e.g., P, S, Pb, and As. Arsenic is a potentially toxic metalloid for most organisms and naturally occurs in trace quantities in soil, rocks, water, air, and living organisms. Among more than 300 arsenic minerals occurring in nature, mimetite [ . Despite the insolubility of mimetite, the organic acid-producing soil fungus Aspergillus niger was able to solubilize mimetite with simultaneous precipitation of lead oxalate as a new mycogenic biomineral. Since fungal biotransformation of both pyromorphite and vanadinite has been previously documented, a new biogeochemical model for the biogenic transformation of lead apatites (mimetite, pyromorphite, and vanadinite) by fungi is hypothesized in this study by application of geochemical modeling together with experimental data. The models closely agreed with experimental data and provided accurate simulation of As and Pb complexation and biomineral formation dependent on, e.g., pH, cation-anion composition, and concentration. A general pattern for fungal biotransformation of lead apatite minerals is proposed, proving new understanding of ecological implications of the biogeochemical cycling of component elements as well as industrial applications in metal stabilization, bioremediation, and biorecovery. F ungi actively contribute to many important geological processes (1-5). Biotransformations and the biogeochemical cycling of elements, metal and mineral transformations, organic matter decomposition, bioweathering, and soil and sediment formation are some of their most important geoactive roles (1-6). Fungal involvement in biogeochemical cycling of essential and potentially toxic elements (e.g., carbon, nitrogen, phosphorus, sulfur, metals, and metalloids) is clear and interlinked with their abilities to adopt a variety of growth, metabolic, and morphological strategies (1-3, 6-12). Fungi are particularly involved in metal biogeochemistry, with a variety of processes determining mobility, and therefore bioavailability, and immobility, leading to formation of secondary minerals and metal stabilization (1-7, 11-13).Arsenic is an element belonging to group V-A and is a metalloid possessing both metallic and nonmetallic properties. Arsenic is widely distributed in the Earth's crust, with an average concentration of 2 to 5 mg kg Ϫ1 , and is associated primarily with igneous and sedimentary rocks in the form of inorganic arsenic compounds (14-17). Arsenic therefore naturally occurs in trace quantities in the lithosphere, hydrosphere, and atmosphere and in all living organisms, where it can be acutely toxic because of its similarity to inorganic phosphate and its affinity for protein thiols (14-16, 18, 19). Arsenate (AsO 4 3Ϫ ) is an analogue of essential phosphate (PO 4 3Ϫ ) and can be taken up via phosphate transport systems in most orga...

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XAS Evidence of As(V) Association with Iron Oxyhydroxides in a Contaminated Soil at a Former Arsenical Pesticide Processing Plant

Cited by 127 publications

References 33 publications

Conversion, sorption, and transport of arsenic species in geological media

Conversion, sorption, and transport of arsenic species in geological media

Mineral-Aqueous Solution Interfaces and Their Impact on the Environment

Fungal Bioweathering of Mimetite and a General Geomycological Model for Lead Apatite Mineral Biotransformations

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