Pressure-induced structural phase transitions of zirconium: An ab initio study based on statistical ensemble theory

Abstract

The structural phase behaviors of pure zirconium metal under compressions up to 160 GPa at room temperature are investigated from the perspective of ensemble theory where the partition function is solved by our recently proposed method with ab initio precision. The derived Gibbs free energy is employed as the very criterion to determine phase transitions and the calculated transition pressures of the α→ω→β are 6.93 and 24.83 GPa respectively, the former one of which is so far the only theoretical result agreeing with multiple experimental measurements to our best knowledge. The differences between the obtained parameter-free equation of state and those from latest experiments are less than 1.5\% in the whole studied pressure range, and particularly, within 0.7\% when the applied pressure exceeds over 40 GPa, the coincidence of which makes us support the argument that the previously observed anharmonicity-driven isostructural phase transition does not exist in the β-phase even though the thermal effects at room temperature are confirmed to be nontrivial to the phase stability by our quantitative comparisons with the results at 0K.