LiH state-to-state rotationally inelastic cross sections in collisions with HCl and DCl

Abstract

A new technique is presented for the determination of state‐to‐state rotationally inelastic cross sections, which employs electric quadrupole state selection and laser fluorescence detection. Results for the scattering of ⁷LiH j=1 molecules by HCl and DCl scattering gas (?_rel= 0.74 eV) are reported. With knowledge of the number density and scattering path length l and the observed invariance of the experimental cross sections with decreased l, absolute integral state‐to‐state cross sections σ_j=1→j′ have been obtained. For both ⁷LiH–HCl and ⁷LiH–DCl, the σ_j=1→j′ values are large (10–200 Ų), the j′=2 level being most probable; the cross sections fall monotonically with increasing j′ out to j′=6, the highest level probed. An unsuspected isotopic enhancement has been observed for the DCl system: All the σ_j=1→j′ values are ∼25% larger for ⁷LiH–DCl than for the corresponding transitions in the ⁷LiH–HCl system. Because both scattering partners have relatively large dipole moments, these systems are paradigms for rotational energy transfer induced by a dipole–dipole interaction. Several theoretical models, which have been widely used to interpret energy transfer in similar systems, are reviewed and compared to these detailed experimental results. It is found that the Born approximation gives cross sections which are far too large and predicts insufficient flux into the higher j′ states, even when higher‐order electrostatic terms are included in the potential. The sudden approximation and the recently introduced adiabatically corrected sudden (ACS) approximation reproduce the experimental cross sections much better both in magnitude and in dependence on j′. The ACS method does significantly better and, in particular, successfully predicts the isotopic enhancement observed in the ⁷LiH–DCl system. The origin of this effect is shown to be due to energetic resonances: For dipole–dipole transitions of the type j_a=1, j_b→j_a±1, j_b∓1, the translational energy defect is less in DCl than HCl for those values of j_b which made the largest contributions to the 298 °K Boltzmann rotational distribution of the hydrogen halides.