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Experimental and theoretical examination of shock-compressed copper through the fcc to bcc to melt phase transitions

Melissa Sims, R. Briggs, Travis J. Volz, Saransh Singh, Sébastien Hamel, A. L. Coleman, F. Coppari, David J. Erskine, M. G. Gorman, Babak Sadigh, Jon Belof, J. H. Eggert, R. F. Smith, J. K. Wicks

2022Journal of Applied Physics35 citationsDOIOpen Access PDF

Abstract

Recent studies show a face-centered cubic (fcc) to body-centered cubic (bcc) transformation along the shock Hugoniot for several metals (i.e., Cu, Au, and Ag). Here, we combine laser-shock compression of Cu foils on nanosecond timescales with in situ x-ray diffraction (XRD) to examine the microstructural changes with stress. We study the fcc phase and the phase transition from fcc to bcc (pressures greater than 180 GPa). Textural analysis of the azimuthal intensities from the XRD images is consistent with transformation into the bcc phase through the Pitsch-distortion mechanism. We use embedded atom model molecular dynamics simulations to determine the stability of the bcc phase in pressure–temperature space. Our results indicate that the bcc phase is stabilized only at high temperatures and remains stable at pressures greater than 500 GPa.

Topics & Concepts

Materials sciencePhase (matter)DiffractionShock (circulatory)Embedded atom modelPhase transitionCopperMolecular dynamicsAtom (system on chip)Condensed matter physicsCrystallographyThermodynamicsMetallurgyChemistryOpticsPhysicsComputational chemistryMedicineComputer scienceInternal medicineEmbedded systemOrganic chemistryHigh-pressure geophysics and materialsDiamond and Carbon-based Materials ResearchIon-surface interactions and analysis
Experimental and theoretical examination of shock-compressed copper through the fcc to bcc to melt phase transitions | Litcius