Predicted electron transport coefficients and operating characteristics of CO2–N2–He laser mixtures

Abstract

Calculations have been made of transport coefficients of electrons in gas mixtures for ratios CO₂:N₂:He of 1:1:8, 1:2:3, 1:7:30, and 1:0.25:3. New cross sections for CO₂ derived from swarm experiments are used together with previously published cross sections for N₂ and He. Curves are presented of the predicted electron drift velocity, transverse and longitudinal diffusion coefficients, and ionization and attachment coefficients for E/N values ranging from 10⁻¹⁸ to 1 × 10⁻¹⁵ V cm²; E is the electric field strength and N the gas number density. Examples are given of derived distribution functions and comparisons are made with a Maxwellian distribution function. The percentage of the input electrical power which excites vibrational processes coupled to the 001 upper laser level of CO₂ is given as a function of E/N. The maximum efficiency from these calculations increases for increasing ratios of N₂:CO₂, because the proportion of energy used to excite the bending and stretching modes of CO₂ is then reduced. By assuming a recombination coefficient of 10⁻⁷ cm³ sec⁻¹, the operating E/N for self‐sustained glow discharges is predicted as a function of current density for various laser mixtures by equating the ionization rate to the attachment and recombination rate.