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Rate constants from the reaction path Hamiltonian. I. Reactive flux simulations for dynamically correct rates
- Source :
- The Journal of Chemical Physics. 121:4453-4460
- Publication Year :
- 2004
- Publisher :
- AIP Publishing, 2004.
-
Abstract
- As ab initio electronic structure calculations become more accurate, inherent sources of error in classical transition state theory such as barrier recrossing and tunneling may become major sources of error in calculating rate constants. This paper introduces a general method for diabatically constructing the transverse eigensystem of a reaction path Hamiltonian in systems with many degenerate transverse frequencies. The diabatically constructed reaction path Hamiltonian yields smoothly varying coupling constants that, in turn, facilitate reactive flux calculations. As an example we compute the dynamically corrected rate constant for the chair to boat interconversion of cyclohexane, a system with 48 degrees of freedom and a number of degenerate frequencies. The transmission coefficients obtained from the reactive flux simulations agree with previous results that have been calculated using an empirical potential. Furthermore, the calculated rate constants agree with experimental values. Comparison to variational transition state theory shows that, despite finding the true bottleneck along the reaction pathway, variational transition state theory only accounts for half of the rate constant reduction due to recrossing trajectories.
- Subjects :
- Coupling constant
Chemistry
Degenerate energy levels
Ab initio
General Physics and Astronomy
Electronic structure
Transition state theory
symbols.namesake
Reaction rate constant
Ab initio quantum chemistry methods
Quantum mechanics
symbols
Physical and Theoretical Chemistry
Hamiltonian (quantum mechanics)
Subjects
Details
- ISSN :
- 10897690 and 00219606
- Volume :
- 121
- Database :
- OpenAIRE
- Journal :
- The Journal of Chemical Physics
- Accession number :
- edsair.doi.dedup.....0567b375eb7b3e72ab99a56530209733
- Full Text :
- https://doi.org/10.1063/1.1778161