Phonon Dispersion Relation, High-Pressure Phase Stability, And Thermal Expansion In Yvo4

The orthovanadates are useful as host matrices for immobilization of radioactive wastes. The thermodynamic stability of these materials is crucial for their applications in high-pressure and high-temperature environment. It is necessary to investigate the phonons in the entire Brillouin zone, beyond the zone-center phonons accessible in previous Raman and infrared experiments. We have carried out extensive neutron inelastic scattering experiments to derive the phonon dispersion relation of YVO4 up to high-energy transfer of 65 meV using a single crystal, which are perhaps reported for the first time in any orthovanadate compound. The measured phonon dispersion relation is in good agreement with our first-principles density functional theory as well as shell-model calculations. The calculated pressure dependence of phonon modes in the zircon and scheelite phases shows unstable modes and violation of the Born stability criteria at high pressure, which may be lead to instability in YVO4 at high pressures. We also calculate large anisotropy in the thermal expansion behavior, which arises from difference in anisotropic elasticity and mode Gruneisen parameters.