Phase Transitions in High Purity Zr Under Dynamic Compression
Abstract
We present results from ramp compression experiments on high-purity Zr that show the α → ω, ω → β, as well as reverse β → ω phase transitions. Simulations with a multi-phase equation of state and phenomenological kinetic model match the experimental wave profiles well. While the dynamic α → ω transition occurs 9 GPa above the equilibrium phase boundary, the ω → β transition occurs within 0.9~GPa of equilibrium. We estimate that the dynamic compression path intersects the equilibrium ω - β line at P= 29.2 GPa, and T = 490 K. The thermodynamic path in the interior of the sample lies 100 K above the isentrope at the point of the ω → β transition. Approximately half of this dissipative temperature rise is due to plastic work, and half is due to the non-equilibrium α → ω transition. The inferred rate of the α → ω transition is several orders of magnitude higher than that measured in dynamic diamond anvil cell (DDAC) experiments in an overlapping pressure range. We discuss a model for the influence of shear stress on the nucleation rate. The small fractional volume change V/V ≈ 0.1 at the α → ω transition amplifies the effect of shear stress, and we estimate that for this case shear stress is equivalent to a pressure increase in the range of several GPa. Correcting our transition rate to a hydrostatic rate brings it approximately into line with the DDAC results, suggesting that shear stress plays a significant role in the transformation rate.
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