Collision-induced first overtone band of gaseous hydrogen from first principles

Document Type

Article

Publication Date

1-1-1993

Abstract

In previous work [Phys. Rev. A 40, 6931 (1989)] the interaction-induced dipole moments of H2 pairs have been obtained by treating the complex of the two molecules like one molecule in the self-consistent-field and size-consistent, coupled-electron pair approximations; from this dipole surface, the binary collision-induced absorption spectra have also been computed for the rototranslational and the fundamental band. In the present work, the radial transition matrix elements of the induced dipole components are obtained for the first overtone band of H2 at 1.2 m. Two cases are here considered: v1=00, v2=02 (single vibrational transition) and v1=0-> 1, v2=01 (double transition), where the vi are the vibrational quantum numbers of two interacting H2 molecules (i=1 or 2). The dependence of these dipole elements on the most important initial and final rotational states (j=0,..., 3) is also evaluated. From these results, the spectral profiles of the collision-induced absorption of molecular hydrogen pairs in the infrared 1.2-m (the first H2 overtone) band are obtained. The calculations are based on a proven isotropic potential model which we have extended to account for the effects of vibrational excitations. The comparison of the computated spectra with the measurements available at temperatures from 24 to 300 K shows agreement within the estimated uncertainties of the best measurements (10%). This fact suggests that theory is capable of predicting these spectra reliably at temperatures for which no measurements exist, with an accuracy that compares favorably with that of good laboratory measurements. © 1993 The American Physical Society.

Publication Title

Physical Review A

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