The α-Effect and Competing Mechanisms: The Gas-Phase Reactions of Microsolvated Anions with Methyl Formate

The enhanced reactivity of alpha-nucleophiles, which contain an electron lone pair adjacent to the reactive site, has been demonstrated in solution and in the gas phase and, recently, for the gas-phase S(N)2 reactions of the microsolvated HOO-(H2O) ion with methyl chloride. In the present work, we continue to explore the significance of microsolvation on the alpha-effect as we compare the gas-phase reactivity of the microsolvated alpha-nucleophile HOO-(H2O) with that of microsolvated normal alkoxy nucleophiles, RO-(H2O), in reactions with methyl formate, where three competing reactions are possible. The results reveal enhanced reactivity of HOO-(H2O) towards methyl formate, and clearly demonstrate the presence of an overall alpha-effect for the reactions of the microsolvated alpha-nucleophile. The association of the nucleophiles with a single water molecule significantly lowers the degree of proton abstraction and increases the S(N)2 and B(AC)2 reactivity compared with the unsolvated analogs. HOO-(H2O) reacts with methyl formate exclusively via the B(AC)2 channel. While microsolvation lowers the overall reaction efficiency, it enhances the B(AC)2 reaction efficiency for all anions compared with the unsolvated analogs. This may be explained by participation of the solvent water molecule in the B(AC)2 reaction in a way that continuously stabilizes the negative charge throughout the reaction.