Depolarization dispersion of a fundamental line of a totally symmetric vibration in resonance Raman scattering

Vibronic coupling of the Herzberg‐Teller type is discussed as a possible source of the depolarization dispersion of a fundamental line of a totally symmetric vibration in resonance Raman scattering (RRS). Two cases are discussed separately. The first case concerns RRS from an electronic state that borrows part of its intensity from a non‐overlapping electronic state of different symmetry. In this case the depolarization ratio of the fundamental line for right angle scattering linearly polarized light can vary between the limits 1/8 and 3/4. The second case arises when part of the intensity is borrowed from an electronic state of the same symmetry but with a transition moment non‐parallel to that of the resonant state. Such a situation can occur in molecules with a symmetry corresponding to one of the following point groups: C 1 , C i , C 2 , C s , C 1 h , C 2 h , S 2 . In this situation the depolarization ratio ρ l can vary between the limits 1/8 and. In both cases the amplitude of the variations of ρ l depends on the damping constant. In the second case the value of the displacement parameter of a totally symmetric mode has a major influence on the range of change of ρ l . Both cases show prominent resonance‐antiresonance coincidences between depolarization dispersions and excitation profiles, which has been previously predicted for non‐totally symmetric modes, and for molecular dimers. It is pointed out that the depolarization ratio in the preresonance region is very sensitive to vibronic coupling and can serve as a probe of such coupling.