A comparison of exact classical and quantum mechanical calculations of vibrational energy transfer

Abstract

Exact classical and quantal calculations of vibrational energy transfer were compared to determine the conditions under which classical mechanics is reliable. A detailed study of collinear collisions between an atom and a harmonic oscillator with a repulsive exponential interaction showed that the average classical and quantal energy transfer agree within a few percent, if the translational energy exceeds the vibrational spacing, and if the average energy transfer does not change sign as the collision energy is varied slightly. Additional collinear calculations with (i) a Morse oscillator and an exponential interaction and (ii) a harmonic oscillator with a Lennard‐Jones interaction confirmed this result, except for the case of a deep potential well. In this case sticky collisions can occur, and the agreement is poorer. For collinear collisions of two harmonic oscillators with a repulsive exponential interaction, the agreement for T→V energy transfer was poorer than in the atom–diatom case. Good agreement was obtained for V→V transfer, with both classical and quantum calculations favoring resonant collisions. In order to calculate individual transition probabilities, a number of classical quantization methods were tested. The two moment method of Truhlar and Duff was found to work well, and was used to calculate integral cross sections for the vibrational relaxation of He+O₂(v=1). For this system a potential energy surface consisting of a harmonic breathing sphere and a repulsive exponential interaction was used to calculate the integral cross sections σ_vv′ for the inelastic transitions v→v′. The classical values of σ₁₀, σ₁₂, σ₁₃, and σ₁₄ calculated by the two moment method were in satisfactory agreement with the quantum results for reduced translational energy ?_t≡E_t/h/ω?1, 2, 4, and 9, respectively. The resulting rate constants k_vv′ were a factor of 2 too small for T≳300 K, and a factor of 1.25 too small for T≳500 K. The usual bin or histrogram method for quantizing the classical energy transfer produced an anomalous threshold of ?_t≳3 for σ₁₀ and σ₁₂, and still higher values for the more endoergic transitions. The resulting k₁₀ was a factor of 10⁶ too small at 300 K and a factor of 2 too small at 1400 K. In addition we found that equating the P₁₀ transition probability with the average reduced energy transfer gave accurate values of k₁₀ for 300 <TP₁₂(P₁₀) with the fraction of trajectories resulting in energy gained (lost) by the oscillator produced excessively high values of k₁₂ and k₁₀. Finally, we found that the Landau–Teller model is in good agreement with the quantum mechanical calculations of k₁₀, k₁₂, and k₁₃, up to a single arbitrary normalization constant.