Abstract
The mechanisms of three selected identity substitution reactions at phosphorus and sulfur occurring with stereospecific inversion have been investigated using density functional theory (DFT). The first identity reaction between methoxyl anion and methyl ethylphenylphosphinate 1 reported in 1963 has been shown to proceed in a stepwise fashion according to the addition–elimination (A–E) mechanism involving formation of a pentacoordinate phosphorus intermediate (TBI-1). In contrast, the results of DFT studies of the identity chloride exchange reaction in (ethoxy)ethylphosphonochloridothionate 3 in acetone solution provided evidence that it proceeds synchronously according to the classical Ingold’s SN2-P mechanism. DFT calculations of the methoxyl–methoxy exchange reaction at sulfur in methyl p-toluenesulfinate 4 catalyzed by trifluoroacetic acid in methanol revealed that it proceeds stepwise (A–E mechanism), involving the formation of the high-coordinate sulfurane intermediate. In both identity transesterification reactions, 1 and 4, the transiently formed trigonal bipyramidal intermediates with the two methoxyl groups occupying apical positions (TBI-1 and TBI-4) have higher free energy barriers for the Berry-type pseudorotation than those for direct decomposition to starting phosphinate and sulfinate ensuring stereospecific inversion of configuration at the phosphinyl and sulfinyl centers. Thus, the DFT method proved its usefulness in the distinction between both mechanisms that are often indistinguishable by kinetic measurements.
Highlights
Publication under the terms and Identity nucleophilic substitution reactions form a specific group of substitution Identity nucleophilic substitution reactions form a specific group ofcenter substitution reacreaction in which the nucleophilic reagent (Nu)-attacking electrophilic (A) at cartionor in heteroatoms which the nucleophilic reagent (Nu)-attacking electrophilic center carbon or bon and the leaving group (Lg) are the same
Nucleophilic substitution reactions at the stereogenic tetrahedral carbon atom proceed in a concerted way (SN 2-C) via a transition state (TS) and are usually accompanied by Walden inversion
In the case of nucleophilic substitution reactions at heteroatoms (P, S, Si), which may form high-coordinate compounds, the inversion of configuration may be observed when they proceed according to the addition–elimination (A–E) stepwise mechanism
Summary
Identity nucleophilic substitution reactions form a specific group of substitution Identity nucleophilic substitution reactions form a specific group ofcenter substitution reacreaction in which the nucleophilic reagent (Nu)-attacking electrophilic (A) at cartionor in heteroatoms which the nucleophilic reagent (Nu)-attacking electrophilic center carbon or bon and the leaving group (Lg) are the same (Scheme 1). Theatstructural heteroatoms the leaving group are the same The structural identityofof identity of Nuand and. A substrate and product, the reversibility Nu and. As well as of a substrate and product, ensures the reversibility of these reactions. As well as of a substrate and product, ensures the reversibility of these reactions. these reactions.
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