As(V) and As(III) reactions on pristine pyrite and on surface-oxidized pyrite

As(V) and As(III) reactions on pristine pyrite and on surface-oxidized pyrite

[Display omitted] ► Pristine pyrite was produced using rigorously anoxic conditions. ► As(III) adsorbed over a broader pH range with this material. ► As(V) was adsorbed, reduced to As(III), and was not released to solution. ► Results with surface-oxidized pyrite were similar to literature reports fo...

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Bibliographic Details
Published in:Journal of colloid and interface science Vol. 388; no. 1; pp. 170 - 175
Main Authors: Sun, Fenglong, Dempsey, Brian A., Osseo-Asare, Kwadwo A.
Format: Journal Article
Language:English
Published: Amsterdam Elsevier Inc 15-12-2012
Elsevier
Subjects:
Adsorption
anaerobic conditions
Arsenate
Arsenic
Arsenic - chemistry
Arsenite
Chemistry
Cleaning
Exact sciences and technology
Exposure
General and physical chemistry
Hydrogen-Ion Concentration
iron
Iron - chemistry
Maintenance
Oxidation
Oxidation-Reduction
oxygen
Oxygen - chemistry
Pyrite
Reduction
Sulfides - chemistry
Sulfur
Surface physical chemistry
XANES
Reduction
Pyrite
Arsenic
Adsorption
Arsenate
XANES
Arsenite
XANES spectrometry
Arsenates
Air
Mechanism
Chemical reduction
pH
Oxidation
Sulfur
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Summary:[Display omitted] ► Pristine pyrite was produced using rigorously anoxic conditions. ► As(III) adsorbed over a broader pH range with this material. ► As(V) was adsorbed, reduced to As(III), and was not released to solution. ► Results with surface-oxidized pyrite were similar to literature reports for pyrite. ► The need for unusual experimental techniques is described. Reactions of As(III) and As(V) with pyrite were investigated using pristine pyrite (produced and reacted in a rigorously anoxic environment with PO2<10−8atm) and using surface-oxidized pyrite (produced under anoxic conditions, exposed to air, then stored and reacted under rigorously anoxic conditions). Results with surface-oxidized pyrite were similar to previously reported arsenic-pyrite results. However As(III) adsorbed over a broader pH range on pristine pyrite than on surface-oxidized pyrite, As(V) adsorbed over a narrower pH range on pristine pyrite than on surface-oxidized pyrite, and adsorbed As(V) on pristine pyrite was reduced to As(III) but adsorbed As(V) was not reduced with surface-oxidized pyrite. Reduction of As(V) with pristine pyrite was first-order in total As(V), Fe(II) was released, and sulfur was oxidized. The proposed mechanism for pyrite oxidation by As(V) was similar to the published mechanism for oxidation by O2 and rates were compared. The results can be used to predict the removals of As(V) and As(III) on pyrite in continuously anoxic environments or on pyrite in intermittently oxic/anoxic environments. Rigorous cleanup and continuous maintenance of strictly anoxic conditions are required if commercial or produced pyrites are to be used as surrogates for pristine pyrite.
Bibliography:http://dx.doi.org/10.1016/j.jcis.2012.08.019
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ISSN:0021-9797
1095-7103
DOI:10.1016/j.jcis.2012.08.019