VIBRATIONAL ENERGY TRANSFER IN CO2 UNDER LASER CONDITIONS WITH AND WITHOUT WATER VAPOR

It is shown that in the case of a dry 1.5-torr CO2 gas fill the upper laser level is indirectly excited by vibrationally excited CO produced during the discharge, whereas in the case of a 1.5-torr CO2 and 0.2-torr H20 mixture the upper laser level is directly excited by the electrons the discharge. The collision relaxation times measured under laser conditions for the symmetric valence vibration of CO2 in a CO2-H20 mixture and in a CO2-CO mixture as produced during a discharge of an initially pure CO2 fill were 19 and 73 µs respectively. If the reasonable assumption was taken that half of the CO2 was dissociated into CO then this result shows that H20 was 14 times more effective in depopulating the lower laser level than CO. The growth in laser intensity for the dry fill was shown to be due to the CO (v = 1) transfer of energy to the asymmetric vibration of CO2 (00°1) with a characteristic increase that was exponential strictly only for a time short compared with the relaxation time of the symmetric vibration. The characteristic transfer time for excitation of the asymmetric vibration was dependent upon the fraction of CO present. If we make the assumption of 50 percent dissociation, the intermolecular energy transfer time between CO and CO2 was found to be 40 torr-µs. Results obtained with N2 and He added to the laser mixture indicated that He was not more effective in relaxing the lower laser level than N2 or CO and was less effective than H20. © 1969 IEEE. All rights reserved.