FeVI, FeV, and FeIV oxidation of cyanide: Elucidating the mechanism using density functional theory calculations

FeVI, FeV, and FeIV oxidation of cyanide: Elucidating the mechanism using density functional theory calculations

[Display omitted] •Density functional theory used to understand cyanide oxidation by FeVI, FeV, FeIV.•Predicted reactivity with HCN as FeV>FeIV>FeVI agrees with experimental rates.•Sequence of oxidation steps is same for all three ferrates but energetics differ.•C-O bond formation is the rate...

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Bibliographic Details
Published in:Chemical engineering journal (Lausanne, Switzerland : 1996) Vol. 330; pp. 1272 - 1278
Main Authors: Terryn, Raymond J., Huerta-Aguilar, Carlos A., Baum, J. Clayton, Sharma, Virender K.
Format: Journal Article
Language:English
Published: Elsevier B.V 15-12-2017
Subjects:
Cyanide
DFT
Electron-transfer
Ferrate
Kinetics
Oxygen-transfer
Cyanide
Ferrate
DFT
Kinetics
Oxygen-transfer
Electron-transfer
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Summary:[Display omitted] •Density functional theory used to understand cyanide oxidation by FeVI, FeV, FeIV.•Predicted reactivity with HCN as FeV>FeIV>FeVI agrees with experimental rates.•Sequence of oxidation steps is same for all three ferrates but energetics differ.•C-O bond formation is the rate determining step for FeVI.•Transfer of H from C to O of ferrate is rate determining step for FeV and FeIV. FeVIO42− (FeVI) is a promising oxidant/disinfectant and coagulant in treating water. FeVO43− (FeV) and FeIVO44− (FeIV) are intermediates in oxidations performed by FeVI and are highly effective in degrading recalcitrant contaminants. The performance of each ferrate requires a comprehensive understanding of the mechanism. This paper presents the use of density functional theory (DFT) to understand the oxidation of cyanide by FeVI, FeV, and FeIV. The sequence of steps in the oxidation process is the same for all three species. The electrostatic attraction of the positive H and C on HCN for two of the negative oxygen atoms on the ferrate is followed by the formation of a C-O bond with cleavage of an Fe-O bond. Subsequently, the formation of an H-O bond occurs with cleavage of the H-C bond, resulting in the formation of an NCO – ferrate complex. However, the energetics are different, with C-O bond formation being the rate determining step for FeVI while for FeV and FeIV it is the transfer of the H from C to O. Energy calculations describe the order of reactivity of ferrates with HCN as FeV>FeIV>FeVI, which agrees well with experimental results.
ISSN:1385-8947
1873-3212
DOI:10.1016/j.cej.2017.08.080