Origin of negative thermal expansion and pressure-induced amorphization in zirconium tungstate from a machine-learning potential
Ri He, Hongyu Wu, Yi Lu, Zhicheng Zhong
Abstract
Understanding various macroscopic pressure-volume-temperature properties of materials on the atomistic level has always been an ambition for physicists and material scientists. Particularly, some materials such as zirconium tungstate (${\mathrm{ZrW}}_{2}{\mathrm{O}}_{8}$), exhibit multiple exotic properties including negative thermal expansion (NTE) and pressure-induced amorphization (PIA). Here, using machine-learning based deep potential, we trace both of the phenomena in ${\mathrm{ZrW}}_{2}{\mathrm{O}}_{8}$ back to a common atomistic origin, where the nonbridging O atoms play a critical role. We demonstrate that the nonbridging O atoms confer great flexibility to vibration of polyhedra, and kinetically drive volume shrinking on heating, or NTE. In addition, beyond a certain critical pressure, we find that the migration of nonbridging O atoms leads to additional bond formation that lowers the potential energy, suggesting that the PIA is a potential-driven first-order phase transition. Most importantly, we identify a second critical pressure beyond which the amorphous phase of ${\mathrm{ZrW}}_{2}{\mathrm{O}}_{8}$ undergoes a ``hidden'' phase transition from a reversible phase to an irreversible one.