Shape of hollow dislocation cores: anisotropic surface energy and elastic effects

Equilibrium morphologies are frequently determined by a competition between interfacial and elastic energies. Holes at the cores of dislocations in materials with large Burgers vectors are a prime example of this type of competition because their existence is solely due to this type of competition....

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Veröffentlicht in:	Scripta Materialia 1998-08, Vol.39 (4), p.379-387
Hauptverfasser:	Srolovitz, D.J., Sridhar, N., Hirth, J.P., Cahn, J.W.
Format:	Artikel
Sprache:	eng
Schlagworte:	Condensed matter: structure, mechanical and thermal properties Defects and impurities in crystals microstructure EDGE DISLOCATIONS EQUILIBRIUM Exact sciences and technology MATERIALS SCIENCE MICROSTRUCTURE MORPHOLOGY NITRIDES OXIDES Physics SCREW DISLOCATIONS SILICATES Structure of solids and liquids crystallography SULFIDES SURFACE ENERGY Theories and models of crystal defects
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container_end_page	387
container_issue	4
container_start_page	379
container_title	Scripta Materialia
container_volume	39
creator	Srolovitz, D.J. Sridhar, N. Hirth, J.P. Cahn, J.W.
description	Equilibrium morphologies are frequently determined by a competition between interfacial and elastic energies. Holes at the cores of dislocations in materials with large Burgers vectors are a prime example of this type of competition because their existence is solely due to this type of competition. In this paper, we presented an approach for addressing these issues both in terms of determination of morphologies for which the energy is an extremum and a procedure for examining the stability of those solutions. We found that the cricular core holes around screw dislocations predicted by Frank are stable in an isotropic material. Core holes around edge dislocations are stable, but are not circular because of the symmetry of their elastic field even in isotropic materials. Even isotropic elastic energy leads to core shapes in which the effect of surface anisotropy is exaggerated over what it would be in the Wulff shape. Most of the present results were derived on the basis of a parametric form for the hole shape and as an expansion of the energies valid for small perturbations about a circular cross-section. Calculations based upon a completely different proposed shape with exact elasticity results led to predictions of hole shapes which are nearly identical.
doi_str_mv	10.1016/S1359-6462(98)00212-7
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Most of the present results were derived on the basis of a parametric form for the hole shape and as an expansion of the energies valid for small perturbations about a circular cross-section. 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Holes at the cores of dislocations in materials with large Burgers vectors are a prime example of this type of competition because their existence is solely due to this type of competition. In this paper, we presented an approach for addressing these issues both in terms of determination of morphologies for which the energy is an extremum and a procedure for examining the stability of those solutions. We found that the cricular core holes around screw dislocations predicted by Frank are stable in an isotropic material. Core holes around edge dislocations are stable, but are not circular because of the symmetry of their elastic field even in isotropic materials. Even isotropic elastic energy leads to core shapes in which the effect of surface anisotropy is exaggerated over what it would be in the Wulff shape. Most of the present results were derived on the basis of a parametric form for the hole shape and as an expansion of the energies valid for small perturbations about a circular cross-section. 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Holes at the cores of dislocations in materials with large Burgers vectors are a prime example of this type of competition because their existence is solely due to this type of competition. In this paper, we presented an approach for addressing these issues both in terms of determination of morphologies for which the energy is an extremum and a procedure for examining the stability of those solutions. We found that the cricular core holes around screw dislocations predicted by Frank are stable in an isotropic material. Core holes around edge dislocations are stable, but are not circular because of the symmetry of their elastic field even in isotropic materials. Even isotropic elastic energy leads to core shapes in which the effect of surface anisotropy is exaggerated over what it would be in the Wulff shape. Most of the present results were derived on the basis of a parametric form for the hole shape and as an expansion of the energies valid for small perturbations about a circular cross-section. Calculations based upon a completely different proposed shape with exact elasticity results led to predictions of hole shapes which are nearly identical.</abstract><cop>New York, NY</cop><pub>Elsevier Ltd</pub><doi>10.1016/S1359-6462(98)00212-7</doi><tpages>9</tpages></addata></record>
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subjects	Condensed matter: structure, mechanical and thermal properties Defects and impurities in crystals microstructure EDGE DISLOCATIONS EQUILIBRIUM Exact sciences and technology MATERIALS SCIENCE MICROSTRUCTURE MORPHOLOGY NITRIDES OXIDES Physics SCREW DISLOCATIONS SILICATES Structure of solids and liquids crystallography SULFIDES SURFACE ENERGY Theories and models of crystal defects
title	Shape of hollow dislocation cores: anisotropic surface energy and elastic effects
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