Alkaline Hydrolysis of Organophosphorus Pesticides: The Dependence of the Reaction Mechanism on the Incoming Group Conformation

The fundamental mechanism of organophosphate hydrolysis is the subject of a growing interest resulting from the need for safe disposal of phosphoroorganic pesticides. Herein, we present a detailed ab initio study of the gas-phase mechanisms of alkaline hydrolysis of P–O and P–S bonds in a number of...

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Published inThe journal of physical chemistry. B Vol. 118; no. 26; pp. 7277 - 7289
Main Authors Dyguda-Kazimierowicz, Edyta, Roszak, Szczepan, Sokalski, W. Andrzej
Format Journal Article
LanguageEnglish
Published United States American Chemical Society 03.07.2014
Subjects
acephate
alkaline hydrolysis
chemical analysis
chemical bonding
Chemical bonds
fenitrothion
gases
Hydrolysis
Lewis bases
malathion
Nucleophiles
Organophosphates
Orientation
oxygen
paraoxon
parathion-methyl
Pathways
Pesticides
phosalone
Physical chemistry
sulfur
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Summary:The fundamental mechanism of organophosphate hydrolysis is the subject of a growing interest resulting from the need for safe disposal of phosphoroorganic pesticides. Herein, we present a detailed ab initio study of the gas-phase mechanisms of alkaline hydrolysis of P–O and P–S bonds in a number of organophosphorus pesticides, including paraoxon, methyl parathion, fenitrothion, demeton-S, acephate, phosalone, azinophos-ethyl, and malathion. Our main finding is that the incoming group conformation influences the mechanism of decomposition of organophosphate and organothiophosphate compounds. Depending on the orientation of the attacking nucleophile, hydrolysis reaction might follow either a multistep pathway characterized by the presence of a pentavalent intermediate or a one-step mechanism proceeding through a single transition state. Despite a widely accepted view of the phosphotriester P–O bonds being decomposed exclusively via a direct-displacement mechanism, the occurrence of alternative, qualitatively distinct reaction pathways was confirmed for alkaline hydrolysis of both P–O and P–S bonds. As the pesticides included in our quantum chemical analysis involve organophosphate, phosphorothioate, and phosphorodithioate compounds, the influence of oxygen to sulfur substitution on the structural and energetic characteristics of the hydrolysis pathway is also discussed.
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ISSN:1520-6106
1520-5207
1520-5207
DOI:10.1021/jp503382j