Vibrational Energy Transfer in CO2 Lasers

Abstract

Laser‐excited vibrational fluorescence measurements have been made on the asymmetric‐stretching vibrational level (00°1) of CO₂. Vibration→vibration energy‐transfer rates from this level due to collisions with CO₂ and with a number of other collision partners are presented. The rate of near‐resonant exchange of vibrational energy between CO₂ and N₂ (ΔE=18 cm⁻¹) has been measured. The kinetics of the CO₂ laser system are analyzed in terms of a three‐level scheme. Observed laser performance is compared with that calculated by use of collisional and radiative coupling rates observed in nonionized gases and of electron activation and deactivation rates estimated from CO₂ discharge systems. In accordance with the scheme presented, the relative effectiveness of small amounts of added H₂, D₂, and He on laser output parallels their effectiveness in deactivating the lower laser level. The criteria for selecting molecules with vibrational‐energy‐level patterns likely to produce laser systems are outlined. Attempts to produce new continuous‐wave lasers in SO₂ and HCN are described.