Dislocation core reconstruction induced by carbon segregation in bcc iron

Lisa Ventelon; B. Lüthi; E. Clouet; L. Proville; B. Legrand; D. Rodney; F. Willaime

doi:10.1103/PhysRevB.91.220102

Dislocation core reconstruction induced by carbon segregation in bcc iron

Lisa Ventelon
, B. Lüthi
, E. Clouet
, L. Proville
, B. Legrand
, D. Rodney
, F. Willaime

CEA Saclay
IGFL, Université de Lyon, Université Lyon 1

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

Abstract

The relative stability of dislocation core configurations in body-centered-cubic metals is profoundly modified by the presence of solutes. Considering the Fe(C) system, we demonstrate by using density functional theory that carbon atoms destabilize the usual easy core to the benefit of the hard core configuration of the screw dislocation, which is unstable in pure metals. The carbon atom is at the center of a regular prism in a cementitelike local environment. The same dislocation core reconstruction is also found with other solutes (B, N, O) and in W(C). This unexpected low-energy configuration induces a strong solute-dislocation attraction, leading to dislocation core saturation by solute atoms, even for very low bulk solute concentrations. This core reconstruction will constitute an essential factor to account for in solute-segregation related phenomena, such as strain aging.

Original language	English
Article number	220102
Journal	Physical Review B - Condensed Matter and Materials Physics
Volume	91
Issue number	22
DOIs	https://doi.org/10.1103/PhysRevB.91.220102
Publication status	Published - 29 Jun 2015
Externally published	Yes

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10.1103/PhysRevB.91.220102

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title = "Dislocation core reconstruction induced by carbon segregation in bcc iron",

abstract = "The relative stability of dislocation core configurations in body-centered-cubic metals is profoundly modified by the presence of solutes. Considering the Fe(C) system, we demonstrate by using density functional theory that carbon atoms destabilize the usual easy core to the benefit of the hard core configuration of the screw dislocation, which is unstable in pure metals. The carbon atom is at the center of a regular prism in a cementitelike local environment. The same dislocation core reconstruction is also found with other solutes (B, N, O) and in W(C). This unexpected low-energy configuration induces a strong solute-dislocation attraction, leading to dislocation core saturation by solute atoms, even for very low bulk solute concentrations. This core reconstruction will constitute an essential factor to account for in solute-segregation related phenomena, such as strain aging.",

author = "Lisa Ventelon and B. L{\"u}thi and E. Clouet and L. Proville and B. Legrand and D. Rodney and F. Willaime",

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doi = "10.1103/PhysRevB.91.220102",

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T1 - Dislocation core reconstruction induced by carbon segregation in bcc iron

AU - Ventelon, Lisa

AU - Lüthi, B.

AU - Clouet, E.

AU - Proville, L.

AU - Legrand, B.

AU - Rodney, D.

AU - Willaime, F.

PY - 2015/6/29

Y1 - 2015/6/29

N2 - The relative stability of dislocation core configurations in body-centered-cubic metals is profoundly modified by the presence of solutes. Considering the Fe(C) system, we demonstrate by using density functional theory that carbon atoms destabilize the usual easy core to the benefit of the hard core configuration of the screw dislocation, which is unstable in pure metals. The carbon atom is at the center of a regular prism in a cementitelike local environment. The same dislocation core reconstruction is also found with other solutes (B, N, O) and in W(C). This unexpected low-energy configuration induces a strong solute-dislocation attraction, leading to dislocation core saturation by solute atoms, even for very low bulk solute concentrations. This core reconstruction will constitute an essential factor to account for in solute-segregation related phenomena, such as strain aging.

AB - The relative stability of dislocation core configurations in body-centered-cubic metals is profoundly modified by the presence of solutes. Considering the Fe(C) system, we demonstrate by using density functional theory that carbon atoms destabilize the usual easy core to the benefit of the hard core configuration of the screw dislocation, which is unstable in pure metals. The carbon atom is at the center of a regular prism in a cementitelike local environment. The same dislocation core reconstruction is also found with other solutes (B, N, O) and in W(C). This unexpected low-energy configuration induces a strong solute-dislocation attraction, leading to dislocation core saturation by solute atoms, even for very low bulk solute concentrations. This core reconstruction will constitute an essential factor to account for in solute-segregation related phenomena, such as strain aging.

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DO - 10.1103/PhysRevB.91.220102

M3 - Article

AN - SCOPUS:84934775102

SN - 1098-0121

VL - 91

JO - Physical Review B - Condensed Matter and Materials Physics

JF - Physical Review B - Condensed Matter and Materials Physics

IS - 22

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Dislocation core reconstruction induced by carbon segregation in bcc iron

Abstract

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