Mode specificity in unimolecular reaction dynamics: The Henon–Heiles potential energy surface
- 1 April 1981
- journal article
- Published by AIP Publishing in The Journal of Chemical Physics
- Vol. 74 (7) , 3910-3915
- https://doi.org/10.1063/1.441567
Abstract
Energies and lifetimes (with respect to tunneling) for metastable states of the Henon–Heiles potential energy surface [V(x,y) = 1/2x2−1/3x3+1/2y2+xy2] have been computed quantum mechanically (via the method of complex scaling). This is a potential surface for which the classical dynamics is known to change from quasiperiodic at low energies to ergodic-like at higher energies. The rate constants (i.e., inverse lifetimes) for unimolecular decay as a function of energy, however, are seen to be well described by standard statistical theory (microcanonical transition state theory, RRKM plus tunneling) over the entire energy region. This is thus another example indicating that mode specificity in unimolecular reaction dynamics is not determined solely by the quasiperiodic/ergodic character of the intramolecular mechanics.Keywords
This publication has 16 references indexed in Scilit:
- Reaction path Hamiltonian: Tunneling effects in the unimolecular isomerization HNC→HCNThe Journal of Chemical Physics, 1980
- Calculations related to quantum stochasticity, an example of overlapping avoided crossingsChemical Physics Letters, 1980
- Properties of vibrational energy levels in the quasi periodic and stochastic regimesThe Journal of Chemical Physics, 1980
- Tunneling corrections to unimolecular rate constants, with application to formaldehydeJournal of the American Chemical Society, 1979
- A nonstatistical unimolecular chemical reaction: isomerization of state-selected allyl isocyanideChemical Physics Letters, 1979
- On possibility of calculating Siegert eigenvalues for autoionizing electronic statesChemical Physics, 1978
- Complex coordinate studies of resonant electron-atom scatteringJournal of Physics B: Atomic and Molecular Physics, 1974
- The Transition from Analytic Dynamics to Statistical MechanicsAdvances in Chemical Physics, 1973
- Complex coordinate space calculations for resonant statesJournal of Physics B: Atomic and Molecular Physics, 1972
- On the Derivation of the Dispersion Formula for Nuclear ReactionsPhysical Review B, 1939