Polycrystalline iron under compression: Plasticity and phase transitions

Nina Gunkelmann; Eduardo M. Bringa; Keonwook Kang; Graeme J. Ackland; Carlos J. Ruestes; Herbert M. Urbassek

doi:10.1103/PhysRevB.86.144111

Polycrystalline iron under compression: Plasticity and phase transitions

Nina Gunkelmann^*, Eduardo M. Bringa, Keonwook Kang, Graeme J. Ackland, Carlos J. Ruestes, Herbert M. Urbassek

^*Corresponding author for this work

School of Physics and Astronomy

Research output: Contribution to journal › Article › peer-review

Abstract

Iron undergoes a bcc to close-packed structural phase transition under pressure, at around 13 GPa, as shown by diamond anvil and shock experiments. Atomistic simulations have been able to provide insights into the transition, but without any plasticity occurring before the phase change, in single crystals, defective single crystals, or polycrystals. However, experiments in polycrystals do show clear evidence for plasticity. Here we study homogeneous uniaxial compression of polycrystalline Fe using several interatomic potentials: three embedded-atom-model potentials and one modified embedded-atom-model potential. We analyze grain-boundary rotation and dislocation activity, and find that the amount of dislocation activity as a function of strain depends greatly on the potential used. This variation can be explained in terms of the dislocation properties, calculated in this work for each of these potentials.

Original language	English
Article number	144111
Number of pages	11
Journal	Physical review B
Volume	86
Issue number	14
DOIs	https://doi.org/10.1103/PhysRevB.86.144111
Publication status	Published - 16 Oct 2012

Keywords / Materials (for Non-textual outputs)

MOLECULAR-DYNAMICS SIMULATIONS
AB-INITIO
NANOCRYSTALLINE MATERIALS
INTERATOMIC POTENTIALS
SCREW DISLOCATIONS
CORE STRUCTURE
ALPHA-IRON
METALS
BCC
CRYSTALS

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10.1103/PhysRevB.86.144111

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title = "Polycrystalline iron under compression: Plasticity and phase transitions",

abstract = "Iron undergoes a bcc to close-packed structural phase transition under pressure, at around 13 GPa, as shown by diamond anvil and shock experiments. Atomistic simulations have been able to provide insights into the transition, but without any plasticity occurring before the phase change, in single crystals, defective single crystals, or polycrystals. However, experiments in polycrystals do show clear evidence for plasticity. Here we study homogeneous uniaxial compression of polycrystalline Fe using several interatomic potentials: three embedded-atom-model potentials and one modified embedded-atom-model potential. We analyze grain-boundary rotation and dislocation activity, and find that the amount of dislocation activity as a function of strain depends greatly on the potential used. This variation can be explained in terms of the dislocation properties, calculated in this work for each of these potentials.",

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author = "Nina Gunkelmann and Bringa, {Eduardo M.} and Keonwook Kang and Ackland, {Graeme J.} and Ruestes, {Carlos J.} and Urbassek, {Herbert M.}",

year = "2012",

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doi = "10.1103/PhysRevB.86.144111",

language = "English",

volume = "86",

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AU - Gunkelmann, Nina

AU - Bringa, Eduardo M.

AU - Kang, Keonwook

AU - Ackland, Graeme J.

AU - Ruestes, Carlos J.

AU - Urbassek, Herbert M.

PY - 2012/10/16

Y1 - 2012/10/16

N2 - Iron undergoes a bcc to close-packed structural phase transition under pressure, at around 13 GPa, as shown by diamond anvil and shock experiments. Atomistic simulations have been able to provide insights into the transition, but without any plasticity occurring before the phase change, in single crystals, defective single crystals, or polycrystals. However, experiments in polycrystals do show clear evidence for plasticity. Here we study homogeneous uniaxial compression of polycrystalline Fe using several interatomic potentials: three embedded-atom-model potentials and one modified embedded-atom-model potential. We analyze grain-boundary rotation and dislocation activity, and find that the amount of dislocation activity as a function of strain depends greatly on the potential used. This variation can be explained in terms of the dislocation properties, calculated in this work for each of these potentials.

AB - Iron undergoes a bcc to close-packed structural phase transition under pressure, at around 13 GPa, as shown by diamond anvil and shock experiments. Atomistic simulations have been able to provide insights into the transition, but without any plasticity occurring before the phase change, in single crystals, defective single crystals, or polycrystals. However, experiments in polycrystals do show clear evidence for plasticity. Here we study homogeneous uniaxial compression of polycrystalline Fe using several interatomic potentials: three embedded-atom-model potentials and one modified embedded-atom-model potential. We analyze grain-boundary rotation and dislocation activity, and find that the amount of dislocation activity as a function of strain depends greatly on the potential used. This variation can be explained in terms of the dislocation properties, calculated in this work for each of these potentials.

KW - MOLECULAR-DYNAMICS SIMULATIONS

KW - AB-INITIO

KW - NANOCRYSTALLINE MATERIALS

KW - INTERATOMIC POTENTIALS

KW - SCREW DISLOCATIONS

KW - CORE STRUCTURE

KW - ALPHA-IRON

KW - METALS

KW - BCC

KW - CRYSTALS

U2 - 10.1103/PhysRevB.86.144111

DO - 10.1103/PhysRevB.86.144111

M3 - Article

SN - 1098-0121

VL - 86

JO - Physical review B

JF - Physical review B

IS - 14

M1 - 144111

ER -

Polycrystalline iron under compression: Plasticity and phase transitions

Abstract

Keywords / Materials (for Non-textual outputs)

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