Electronic and vibrational energy transfer and relaxation in crystalline ϱ-dibromodenzene

Fluorescence spectn of the isotopic mixtures: glyoxnl42 -glyoxakfz were studied upon selective single-vibroniclevel excitation. It is shown that the electionic-energy transfer between isotopic species is efficient md determines the rate of the vibrational relaxation. '.

We show that, in vibrational rehxation experiments. the excitation process prepares a11 the molecules in a coherent, or Gkwber, stnte-We then cafcukae the dephasinz rate due to resonant energy transfer. We also gibe another demonstration of relationships betseen the different rehlation times in simp

Vibrational coherence recently observed by Vos et al. has been analyzed to determine the rate of vibrational relaxation involved in the primary electron transfer (ET) in reaction centers. A modified ET model is introduced to determine multi-mode effects and the temperature dependence of ET for a ser