Presentation1_Atomic Insight Into Phase Transition Lowering in Shock Compressed Copper.pdf
High pressure structural transformation of copper (Cu) is a rather complex physical process. One of the intriguing questions that are rarely discussed is the comparison between quasi-isentropic response and adiabatic response for copper lattice transition. The ambient face-centered-cubic structure of Cu is predicted to persist over 100 TPa from ab inito calculations and experimentally demonstrated to persist until 1.15 TPa in ramp compression and 150 GPa in static compression. However, a novel body-centered-cubic (BCC) order is observed merely at 180 GPa once shock compression is applied. The mechanism of body-centered-cubic phase transition occurred at low pressure under shock compression remains elusive so far and much attention is required on the dynamics in such a phase transition. In this work, we utilize the molecular dynamics method to simulate the shock compression on a copper lattice to uncover the structural transition in the atomic scale. We report the FCC–BCC phase transition occurred at 156 GPa, and lots of disordered structures are discovered in the BCC phase after impact, revealed by a series of structure analysis tools and free energy calculations. The plethora of transient disordered structures reduces the global Gibbs free energies, thus leading to the downgrade of the transition pressure in contrast to the ramp and static compression, which provides a new perspective for structural transformation under extreme conditions.
History
Usage metrics
Categories
- Biophysics
- Classical Physics not elsewhere classified
- Condensed Matter Physics not elsewhere classified
- Quantum Physics not elsewhere classified
- Solar System, Solar Physics, Planets and Exoplanets
- Mathematical Physics not elsewhere classified
- Classical and Physical Optics
- Astrophysics
- Photonics, Optoelectronics and Optical Communications
- Physical Chemistry of Materials
- Cloud Physics
- Tropospheric and Stratospheric Physics
- Physical Chemistry not elsewhere classified
- Applied Physics
- Computational Physics
- Condensed Matter Physics
- Particle Physics
- Plasma Physics
- High Energy Astrophysics; Cosmic Rays
- Mesospheric, Ionospheric and Magnetospheric Physics
- Space and Solar Physics