Lattice vibrations ofγ- andβ-coronene from Raman microscopy and theory

Abstract

We combine polarization-resolved low frequency Raman microscopy and dispersion-corrected density-functional calculations (DFT-D3) to study polymorph-dependent lattice vibrations in coronene, a model molecular system for nanographenes and disc-like organic semiconductors that exhibits two crystalline structures with distinct electronic and optical properties. Changes in low energy Raman-active lattice phonons are followed across the {\gamma}- to \b{eta}-phase transition at 150 K. Raman frequencies calculated using DFT-D3 agree to within 4 cm-1, and on the basis of polarisation dependence of peak positions and intensities we achieve a clear mode assignment. Studies of the associated atomic motions show how the pure librational and rotational modes of {\gamma}-coronene change into mixed roto-librations in the \b{eta}-phase, explaining the remarkable differences in Raman spectra of the two phases.