The interaction between extended dislocations and antiphase domain boundaries - II: Uncoupled superpartial dislocations and planar slip

Tiesheng Rong; Mark Aindow; Ian Jones

doi:10.1016/S0966-9795(01)00032-2

The interaction between extended dislocations and antiphase domain boundaries - II: Uncoupled superpartial dislocations and planar slip

Tiesheng Rong, Mark Aindow, Ian Jones

Metallurgy and Materials

Research output: Contribution to journal › Article

5 Citations (Scopus)

Abstract

Due to their interactions with antiphase domain boundaries, superdislocations can move effectively as uncoupled superpartial dislocations in ordered structures. It is shown that there is a critical domain size below which this will occur irrespective of the grain size and APE energy. Our analysis also indicates that, because of superdislocation/domain boundary interactions, the stress required to move a superdislocation on a 'fresh' slip plane is maximum. Once superdislocations glide over a slip plane, an increasingly easy slip channel is created for the following superdislocations gliding on the same plane. Therefore, planar slip is expected. The smaller the APD size, the more likely is planar slip. (C) 2001 Elsevier Science Ltd. All rights reserved.

Original language	English
Pages (from-to)	507
Number of pages	1
Journal	Intermetallics
Volume	9
Issue number	6
DOIs	https://doi.org/10.1016/S0966-9795(01)00032-2
Publication status	Published - 1 Jun 2001

Keywords

mechanical properties, theory

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10.1016/S0966-9795(01)00032-2

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abstract = "Due to their interactions with antiphase domain boundaries, superdislocations can move effectively as uncoupled superpartial dislocations in ordered structures. It is shown that there is a critical domain size below which this will occur irrespective of the grain size and APE energy. Our analysis also indicates that, because of superdislocation/domain boundary interactions, the stress required to move a superdislocation on a 'fresh' slip plane is maximum. Once superdislocations glide over a slip plane, an increasingly easy slip channel is created for the following superdislocations gliding on the same plane. Therefore, planar slip is expected. The smaller the APD size, the more likely is planar slip. (C) 2001 Elsevier Science Ltd. All rights reserved.",

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N2 - Due to their interactions with antiphase domain boundaries, superdislocations can move effectively as uncoupled superpartial dislocations in ordered structures. It is shown that there is a critical domain size below which this will occur irrespective of the grain size and APE energy. Our analysis also indicates that, because of superdislocation/domain boundary interactions, the stress required to move a superdislocation on a 'fresh' slip plane is maximum. Once superdislocations glide over a slip plane, an increasingly easy slip channel is created for the following superdislocations gliding on the same plane. Therefore, planar slip is expected. The smaller the APD size, the more likely is planar slip. (C) 2001 Elsevier Science Ltd. All rights reserved.

AB - Due to their interactions with antiphase domain boundaries, superdislocations can move effectively as uncoupled superpartial dislocations in ordered structures. It is shown that there is a critical domain size below which this will occur irrespective of the grain size and APE energy. Our analysis also indicates that, because of superdislocation/domain boundary interactions, the stress required to move a superdislocation on a 'fresh' slip plane is maximum. Once superdislocations glide over a slip plane, an increasingly easy slip channel is created for the following superdislocations gliding on the same plane. Therefore, planar slip is expected. The smaller the APD size, the more likely is planar slip. (C) 2001 Elsevier Science Ltd. All rights reserved.

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The interaction between extended dislocations and antiphase domain boundaries - II: Uncoupled superpartial dislocations and planar slip

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