Pyrite (FeS₂) oxidation: a sub-micron synchrotron investigation of the initial steps
Date
2011
Authors
Chandra, A.P.
Gerson, A.R.
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Journal article
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Geochimica et Cosmochimica Acta, 2011; 75(20):6239-6254
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Abstract
Pyrite is an environmentally significant mineral being the major contributor to acid rock drainage. Synchrotron based SPEM (scanning photoelectron microscopy) and micro-XPS (X-ray photoelectron spectroscopy) have been used to characterise fresh and oxidised pyrite (FeS₂) with a view to understanding the initial oxidation steps that take place during natural weathering processes. Localised regions of the pyrite surface containing Fe species of reduced coordination have been found to play a critical role. Such sites not only initiate the oxidation process but also facilitate the formation of highly reactive hydroxyl radical species, which then lead the S oxidation process.
Four different S species are found to be present on fresh fractured pyrite surfaces: S₂²⁻₍bᵤₗₖ₎ (4-fold coordination), S₂²⁻₍ₛᵤᵣfₐcₑ₎ (3-fold coordination), S²⁻ and S⁰/Sₙ²⁻ (metal deficient sulfide and polysulfide respectively). These species were found to be heterogeneously distributed on the fractured pyrite surface. Both O₂ and H₂O gases are needed for effective oxidation of the pyrite surface. The process is initiated when O₂ dissociatively and H₂O molecularly adsorb onto the surface Fe sites where high dangling bond densities exist. H₂O may then dissociate to produce radical ˙OH radicals. The adsorption of these species leads to the formation of Fe-oxy species prior to the formation of sulfoxy species. Evidence suggests that Fe–O bonds form prior to Fe–OH bonds. S oxidation occurs through interactions of radical ˙OH radicals formed at the Fe sites, with formation of SO₄²⁻ occurring via S₂O₃²⁻/SO₃²⁻ intermediates. The pyrite oxidation process is electrochemical in nature and was found to occur in patches, where site specific adsorption of O₂ and H₂O has occurred. Fe and S oxidation was found to occur within the same area of oxidation probably in atomic scale proximity. Furthermore, the O in SO₄²⁻ arises largely from H₂O; however, depending on the surface history, SO₄²⁻ formed early in the oxidation process may also contain O from O₂.
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Data source: Supplementary data, https://doi.org/10.1016/j.gca.2011.08.005
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Copyright 2011 Elsevier