Diatomic Gasdynamic Lasers
- 1 December 1972
- journal article
- conference paper
- Published by AIP Publishing in Physics of Fluids
- Vol. 15 (12) , 2163-2173
- https://doi.org/10.1063/1.1693852
Abstract
Predictions from a numerical model of the vibrational relaxation of anharmonic diatomic oscillators in supersonic expansions are used to show the extent to which the small anharmonicity of gases like CO can cause significant overpopulations of upper vibrational states. When mixtures of CO and N2 are considered, radiative gain on many of the vibration‐rotation transitions of CO is predicted. Experiments are described that qualitatively verify the predictions by demonstrating laser oscillation in CO‐N2 expansions. The resulting CO‐N2 gasdynamic laser displays performance characteristics that equal or exceed those of similar CO2 lasers.Keywords
This publication has 25 references indexed in Scilit:
- Calculations of V–V Transfer Probabilities in CO–CO CollisionsThe Journal of Chemical Physics, 1971
- Quenching of Infrared Chemiluminescence 1: The Rates of De-Excitation of CO (4 ≤ v ≤ 13) by He, CO, NO, N_2, O_2, OCS, N_2O, and CO_2Applied Optics, 1971
- Anharmonic Effects in the Vibrational Relaxation of Diatomic Molecules in Expanding FlowsApplied Optics, 1971
- Observations of Vibration–Vibration Energy Pumping between Diatomic MoleculesNature, 1970
- Numerical Integration of the Equations Governing the One-Dimensional Flow of a Chemically Reactive GasPhysics of Fluids, 1969
- Survey of Vibrational Relaxation Data for Processes Important in the C-Laser SystemReviews of Modern Physics, 1969
- Vibrational relaxation of anharmonic oscillator molecules: Relaxation under isothermal conditionsJournal of Physics B: Atomic and Molecular Physics, 1968
- Vibrational Relaxation of CO in Nonequilibrium Nozzle FlowThe Journal of Chemical Physics, 1968
- Vibrational-Rotational Laser Action in Carbon MonoxidePhysical Review B, 1966
- Computer solutions to the problem of vibrational relaxation in hypersonic nozzle flowsJournal of Fluid Mechanics, 1964