First-principles equations of state for simulations of shock waves in silicon

D.C. Swift; G.J. Ackland; A. Hauer; G.A. Kyrala

First-principles equations of state for simulations of shock waves in silicon

D.C. Swift, G.J. Ackland, A. Hauer, G.A. Kyrala

School of Physics and Astronomy

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Abstract

We have calculated a thermodynamically complete equation of state for silicon, based on ab initio predictions of the electron ground states and quasiharmonic phonons, and incorporating phase transitions between crystal structures. The equation of state was in reasonable agreement with data on the shock Hugoniot. We also used the equation of state in continuum mechanical simulations to investigate the splitting of a shock wave, caused by phase transition from the diamond structure. Good agreement is observed, which can be made exact by adjusting the ab initio results to account for the known overbinding effects of the local-density approximation. The predictions were consistent with recent transient x-ray diffraction data on silicon.

Original language	English
Pages (from-to)	2141071-21410714
Number of pages	19269644
Journal	Physical review B
Volume	64
Issue number	21
Publication status	Published - 2001

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title = "First-principles equations of state for simulations of shock waves in silicon",

abstract = "We have calculated a thermodynamically complete equation of state for silicon, based on ab initio predictions of the electron ground states and quasiharmonic phonons, and incorporating phase transitions between crystal structures. The equation of state was in reasonable agreement with data on the shock Hugoniot. We also used the equation of state in continuum mechanical simulations to investigate the splitting of a shock wave, caused by phase transition from the diamond structure. Good agreement is observed, which can be made exact by adjusting the ab initio results to account for the known overbinding effects of the local-density approximation. The predictions were consistent with recent transient x-ray diffraction data on silicon.",

author = "D.C. Swift and G.J. Ackland and A. Hauer and G.A. Kyrala",

note = "Cited By (since 1996):26 Export Date: 22 November 2013 Source: Scopus Art. No.: 214107",

year = "2001",

language = "English",

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journal = "Physical review B",

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T1 - First-principles equations of state for simulations of shock waves in silicon

AU - Swift, D.C.

AU - Ackland, G.J.

AU - Hauer, A.

AU - Kyrala, G.A.

N1 - Cited By (since 1996):26 Export Date: 22 November 2013 Source: Scopus Art. No.: 214107

PY - 2001

Y1 - 2001

N2 - We have calculated a thermodynamically complete equation of state for silicon, based on ab initio predictions of the electron ground states and quasiharmonic phonons, and incorporating phase transitions between crystal structures. The equation of state was in reasonable agreement with data on the shock Hugoniot. We also used the equation of state in continuum mechanical simulations to investigate the splitting of a shock wave, caused by phase transition from the diamond structure. Good agreement is observed, which can be made exact by adjusting the ab initio results to account for the known overbinding effects of the local-density approximation. The predictions were consistent with recent transient x-ray diffraction data on silicon.

AB - We have calculated a thermodynamically complete equation of state for silicon, based on ab initio predictions of the electron ground states and quasiharmonic phonons, and incorporating phase transitions between crystal structures. The equation of state was in reasonable agreement with data on the shock Hugoniot. We also used the equation of state in continuum mechanical simulations to investigate the splitting of a shock wave, caused by phase transition from the diamond structure. Good agreement is observed, which can be made exact by adjusting the ab initio results to account for the known overbinding effects of the local-density approximation. The predictions were consistent with recent transient x-ray diffraction data on silicon.

M3 - Article

SN - 1098-0121

VL - 64

SP - 2141071

EP - 21410714

JO - Physical review B

JF - Physical review B

IS - 21

ER -

First-principles equations of state for simulations of shock waves in silicon

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