Very highly excited vibrational states of LiCN using a discrete variable representation
- 1 March 1990
- journal article
- research article
- Published by Taylor & Francis in Molecular Physics
- Vol. 69 (4) , 639-648
- https://doi.org/10.1080/00268979000100471
Abstract
Calculations are presented for the lowest 900 vibrational (J = 0) states of the LiCN floppy system for a two dimensional potential energy surface (r CN frozen). Most of these states lie well above the barrier separating the two linear isomers of the molecule and the point where the classical dynamics of the system becomes chaotic. Analysis of the wavefunctions of individual states in the high energy region shows that while most have an irregular nodal structure, a significant number of states appear regular—corresponding to solutions of standard, ‘mode localized’ hamiltonians. Motions corresponding in zero-order to Li-CN and Li-NC normal modes as well as free rotor states are identified. The distribution of level spacings is also studied and yields results in good agreement with those obtained by analysing nodal structures.Keywords
This publication has 16 references indexed in Scilit:
- Highly excited rovibrational states using a discrete variable representation: The H+3 molecular ionThe Journal of Chemical Physics, 1989
- Comparison of classical and quantum phase space structure of nonrigid molecules, LiCNChemical Physics Letters, 1989
- Highly excited vibrational levels of ‘‘floppy’’ triatomic molecules: A discrete variable representation—Distributed Gaussian basis approachThe Journal of Chemical Physics, 1986
- Transition intensities and fluorescence lifetimes for regular and chaotic states of LiCNChemical Physics, 1986
- Routes to vibrational chaos in triatomic moleculesChemical Physics, 1985
- Quantum and classical vibrational chaos in floppy moleculesThe Journal of Chemical Physics, 1985
- A b i n i t i o dipole surfaces, vibrationally averaged dipole moments, and infrared transition intensities for KCN and LiCNThe Journal of Chemical Physics, 1984
- Ab initio rovibrational spectrum of LiNC and LiCNJournal of Molecular Spectroscopy, 1983
- An SCF potential energy surface for lithium cyanideChemical Physics Letters, 1982
- Vibration-rotation problem for triatomic molecules with two large-amplitude coordinatesJournal of Molecular Spectroscopy, 1977