Tunable raman excitation and vibrational relaxation in diatomic molecules

Theoretical analysis of the time-dependent triplet-triplet absorption spectrum of anrhracene is cvried out in terms of the Huanp-Rhys spectral function which describes the absorption of molecules thermally equilibrated, due to fast intramolecular processes, al some effective tempera!urc r\*(r) depen

Differences between vibrational and rotational rehsation patterns disappex and similarities are reveaIed by\_trxtsforming from stite to er.ergy distributions\_ This IblIows from the constant state density of both osciilators and rotors and the exponential gap 1zw governing their relaxation A simple.

## Vlbrational-rotatlonal couphng, due to the fact that the center of interaction IS displaced from the center of mass in a heteronuclear diitomrc molecule, provides a mechanism for nonradiatwe vibrational relazxation of diitomic impurities in matrlces. A theoretical expresaon for the rate constan

For the vibration-rotational motion of a diatomic molecule, various forms of an effective Hamiltonian which includes the corrections of the Born-Oppenheimer approximation in the form of radial functions are reviewed. A procedure to fit vibration-rotational and pure rotational transitions is proposed

A simple algebraic form for the dipole operator which allows for overtone transitions is introduced and discussed. The proposed operator has the flexibility to reproduce the known qualitative features of the Einstein coefficients for anharmonic molecules. It can also be used to quantitatively accoun