Alan D. Isaacson scite author profile

A formalism for the application of variational transition-state theory and semiclassical vibrationally adiabatic transmission coefficients to bimolecular reactions involving an arbitrary number of atoms is presented. This generalizes previous work on atom-diatom reactions. We make applications in this paper to the reactions OH + H,--H,o + Hand OH + D,--HDO + D using the Schatz-Elgersma fit to the Walch-Dunning ab initio potential energy surface. For both reactions we find large differences between conventional and variational transition-state theory and large effects of anharmonicity on the calculated rate constants. The effect of reaction-path curvature on the calculated transmission coefficients and rate constants is also large. The final calculated values of the kinetic isotope effects are in good agreement with experiment at high temperature but too large at room temperature.

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Simple perturbation theory estimates of equilibrium constants from force fields

Truhlar

Isaacson

1991

116

104

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General method for removing resonance singularities in quantum mechanical perturbation theory

Kuhler¹,

Truhlar²,

Isaacson³

1996

104

101

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Articles you may be interested inMøller-Plesset perturbation theory gradient in the generalized hybrid orbital quantum mechanical and molecular mechanical method This paper presents a way of improving second-order perturbation theory calculations by summing contributions of uncoupled excitations to infinite order. For problems involving molecular vibrations, the new theory is shown to give similar results to conventional second-order perturbation theory when the system treated has no near resonances but also to give accurate and stable results even very close to resonance. The new theory is tested by comparison to converged variational calculations for vibrational energy levels of formaldehyde, formaldehyde-d 2 , and two two-dimensional model subsystems based on formaldehyde.

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Alan D. Isaacson

POLYRATE 4: A new version of a computer program for the calculation of chemical reaction rates for polyatomics

Incorporation of quantum effects in generalized-transition-state theory

Polyatomic canonical variational theory for chemical reaction rates. Separable-mode formalism with application to OH+H2→H2O+H

Simple perturbation theory estimates of equilibrium constants from force fields

General method for removing resonance singularities in quantum mechanical perturbation theory

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