Low-frequency Raman spectroscopy of deuterium to megabar pressures at 77-295 K

Abstract

Rotational and lattice phonon excitations in the Raman spectrum of solid molecular deuterium have been measured from 1.8 GPa to ∼200 GPa at 77-295 K to study pressure-induced changes in structural and dynamical properties of the dense solid. Continuous and discontinuous changes in three distinct pressure ranges are observed. At lower pressures (${\mathit{S}}_0$(0) band, together with gradually decreasing resolution of the higher-energy ${\mathit{S}}_0$(1) and ${\mathit{S}}_0$(2) features. At intermediate pressures (60–100 GPa), a change in the pressure dependence and linewidth of ${\mathit{S}}_0$(0), and a linewidth and intensity decrease in the ${\mathit{E}}_{2\mathit{g}}$ phonon band occur. This is interpreted as evidence for a phase transformation in the molecular solid beginning at ∼65 GPa (77 K). At the highest pressures (∼160 GPa), abrupt changes in the low-frequency excitations suggest either an expansion of the molecular bond or a change in ordering at the vibron discontinuity. Evidence from the low-frequency spectra for interaction between the deuterium sample and diamond anvil is also examined.