F.E. Wilkinson, M. Peschke, J.E. Szulejko, T.B. McMahon
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引用次数: 9
Abstract
Fourier Transform Ion Cyclotron Resonance (FT-ICR) and High Pressure Mass Spectrometric (HPMS) measurements of the deuterium isotope effect and kinetics of adduct ion formation have been used to probe the nature of the potential describing the motion of the hydrogen in gas phase ion-molecule hydrogen-bonding interactions. Hydrogen-bonding systems reported in this paper are alkoxide ion and chloride ion solvated by one molecule of alcohol, ROH●OR- and ROH●Cl-. Significant differences in the isotope effects were observed for the two systems. These differences are explained on the basis of the differing hydrogen bond strengths of the adduct ions, and the ability of the chloride ion to partake in multiple site, or chelate, interactions. In addition, HPMS studies of the kinetics of the reaction of CH3O− with CH3OH reveal that a double minimum potential energy surface may be appropriate for describing the adduct ion formation. These experimental studies have been supplemented by ab initio calculations to determine adduct ion structures as well as to permit statistical thermodynamic calculations of the isotope effect.
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