Crystal-split electronic states of an atom in a rare gas crystal. Calculation of the absorption and fluorescence spectra of trapped oxygen (3P, 1D, 1S) atoms
- 1 May 1983
- journal article
- research article
- Published by AIP Publishing in The Journal of Chemical Physics
- Vol. 78 (9), 5480-5492
- https://doi.org/10.1063/1.445476
Abstract
A method is proposed to determine the (crystal perturbed) energy levels of a guest species at any point inside the trapping site of an inclusion distorted host crystal. It relies on available pair potential energy curves, usually deduced from ab initio data supplemented by long‐range dispersion energy when necessary. It is applied here to oxygen in its atomlike 3P, 1D or 1S state imbedded in Ne, Ar, Kr, and Xe matrix and allows reproduction of transition energies within 0.03 eV, and other experimental features. Its broad field of application could find many other exploitations, some of which are proposed.Keywords
This publication has 25 references indexed in Scilit:
- The influence of a rare-gas matrix on the electronic levels of isolated atomsThe Journal of Chemical Physics, 1980
- Theoretical treatment of the spin–orbit coupling in the rare gas oxides NeO, ArO, KrO, and XeOThe Journal of Chemical Physics, 1980
- Spin–orbit coupling and inelastic transitions in collisions of O(1D) with Ar, Kr, and XeThe Journal of Chemical Physics, 1979
- Collisional quenching of O(1 D) by rare gas atomsJournal of the Chemical Society, Faraday Transactions 2: Molecular and Chemical Physics, 1978
- A prioricalculation of thevalence exciton of solid neonPhysical Review B, 1977
- Low-lying electronic states of the rare gas oxidesThe Journal of Chemical Physics, 1977
- The possibility of high-energy-storage lasers using the auroral and transauroral transitions of column-VI elementsJournal of Applied Physics, 1976
- Intermolecular potential parameters of some electronic excited states of atoms and moleculesChemical Physics Letters, 1969
- Environmental perturbations on foreign atoms and molecules in solid argon, krypton and xenonMolecular Physics, 1959
- Electronic Spectral Shifts of Nonpolar Molecules in Nonpolar SolventsThe Journal of Chemical Physics, 1957