Relaxation of internal energy and collisional energy transfer

Clasc~cal trajectories were run simulating the collision of a diatomic molecule with a sohd surface on a realistic potential energ+ surf.~cc. Previous model potentials have been gcnerslizcd to include I.Wicc dynzurucs in the solid surface snd, hence, the possibility of gas-solid energy tranGx. This

It is shown that the optimal means of tabulating collisional energy transfer parameters in gas-phase uni-and ter-molecular reactions is as the average downward energy transfer, rather than the total energy transferred or the collision efficiency.

Recently, Gilbert and Zare proposed that dynamical quantum effects might explain the poor performance ofclassical trajectory calculations in simulating the vibrational deactivation of excited azulene by the lighter noble gases. They proposed an experimental test: a comparison of 3He and 4He deactiva

The effect of resonant intramolecular interactions upon vibrational energy transfer is studied using classical and quantum perturbation theory. It is shown that cancellations attributed previously to quantum interference may equally well be ascribed to a classical mechanism.