High-pressure phase diagram of beryllium from <i>ab initio</i> free-energy calculations
Ji-Zhou Wu, Felipe González‐Cataldo, Burkhard Militzer
Abstract
We use first-principles molecular dynamics simulations coupled with the thermodynamic integration method to study the hexagonal close-packed (hcp) to body-centered cubic (bcc) transition and melting of beryllium up to a pressure of 1600 GPa. We derive the melting line by equating solid and liquid Gibbs free energies and represent it by a Simon-Glatzel fit ${T}_{m}=1564\phantom{\rule{0.16em}{0ex}}\text{K}{[1+P/(15.6032\phantom{\rule{0.16em}{0ex}}\text{GPa})]}^{0.383}$, which is in good agreement with previous two-phase simulations 6000 K. We also derive the hcp-bcc solid-solid phase boundary and show that the quasiharmonic approximation underestimates the stability of the hcp structure, predicting lower transition pressures between hcp and bcc phases. Our results are consistent with the stability regime predicted by the phonon quasiparticle method. We also predict that the hcp-bcc-liquid triple point is located at 164.7 GPa and 4314 K. In addition, we compute the shock Hugoniot curve and show that it is in good agreement with experiments, intersecting our derived melting curve at $\ensuremath{\sim}235$ GPa and 4900 K. Finally, we make predictions for future ramp compression experiments. Starting with an isentropic compression of the liquid, we predict the path to intersect the melting line at low pressure and temperature, then to continue along the melting line over a large temperature interval of 7000 K as the sample remains in the mixed solid-liquid state before it enters the solid phase.