A state-to-state statistical-dynamical theory for large molecule collisional energy transfer

The quantum mechanical energy is examined in which groups of one, two, three, and four localized electron pairs found within a molecule are separately computed. From these results, the interaction energies of the electron pairs taken one, two, three, and four at a time form the terms of a convergent

A model for the dynamics of high Rydberg states in isolated large molecules is proposed. The model accounts for the interaction between the electron and the vibrational degrees of freedom of the core. These are modelled by an Ohmic bath in thermal equilibrium. A reduced-density-matrix description is

Rigorous quantum dynamics simulations have been performed to test the path-integral centroid formulation proposed by Voth, Chandler and Miller for quanta1 rate constants in a simple class of models for electron transfer reactions in the tight-binding limit. Fully dynamical quantum Monte Carlo simul

Quenching of electronic eaciration by collisional transfer into vibration is quantirativrly truared. assuming sudden release of the escitation near the classical turning point. For the H, o\*-sensitized ZR fluorescence of CO, the calculated vibrational distribution reproduces the experimental result