A phase-field model of dislocations on parallel slip planes
A phase-field model of dislocations on parallel slip planes
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DissertationDate of Exam
20.12.2016Date of Publication
10.03.2017Advisor
Conti, SergioCo-Referee
Müller, StefanMetadata
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Abstract
We expand the Peierls-Nabarro phase-field model of dislocations on one active slip plane introduced by Koslowski, Cuitiño, and Ortiz to the case of multiple parallel slip planes embedded into a homogeneous anisotropic crystal. We deduce the leading-order behavior of the energy as lattice size and slip plane spacing tend to zero. Under a logarithmic rescaling, the limit energy in the sense of Γ-convergence takes the form of a line-tension functional supported on dislocation lines featuring interactions between parallel dislocation lines in different slip planes. An optimal dislocation configuration is shown to contain a two-scale microstructure.
This is an extension of a result by Conti, Garroni, and Müller. We are able to treat anisotropic materials with possibly nonpositive interaction kernels, and obtain the leading order energy for non-dilute dislocations in a special geometry. We use the theory of functions of bounded variation, the fractional Sobolev space H1/2, and linear elasticity theory. We show some new results using iterated mollification and multiscale analysis, and use a modified ball construction for an extension result in BV.
This is an extension of a result by Conti, Garroni, and Müller. We are able to treat anisotropic materials with possibly nonpositive interaction kernels, and obtain the leading order energy for non-dilute dislocations in a special geometry. We use the theory of functions of bounded variation, the fractional Sobolev space H1/2, and linear elasticity theory. We show some new results using iterated mollification and multiscale analysis, and use a modified ball construction for an extension result in BV.
Classification (DDC)
510 MathematikGladbach, Peter: A phase-field model of dislocations on parallel slip planes. - Bonn, 2017. - Dissertation, Rheinische Friedrich-Wilhelms-Universität Bonn.
Online-Ausgabe in bonndoc: https://nbn-resolving.org/urn:nbn:de:hbz:5n-45984
Online-Ausgabe in bonndoc: https://nbn-resolving.org/urn:nbn:de:hbz:5n-45984
@phdthesis{handle:20.500.11811/7099,
urn: https://nbn-resolving.org/urn:nbn:de:hbz:5n-45984,
author = {{Peter Gladbach}},
title = {A phase-field model of dislocations on parallel slip planes},
school = {Rheinische Friedrich-Wilhelms-Universität Bonn},
year = 2017,
month = mar,
note = {We expand the Peierls-Nabarro phase-field model of dislocations on one active slip plane introduced by Koslowski, Cuitiño, and Ortiz to the case of multiple parallel slip planes embedded into a homogeneous anisotropic crystal. We deduce the leading-order behavior of the energy as lattice size and slip plane spacing tend to zero. Under a logarithmic rescaling, the limit energy in the sense of Γ-convergence takes the form of a line-tension functional supported on dislocation lines featuring interactions between parallel dislocation lines in different slip planes. An optimal dislocation configuration is shown to contain a two-scale microstructure.
This is an extension of a result by Conti, Garroni, and Müller. We are able to treat anisotropic materials with possibly nonpositive interaction kernels, and obtain the leading order energy for non-dilute dislocations in a special geometry. We use the theory of functions of bounded variation, the fractional Sobolev space H1/2, and linear elasticity theory. We show some new results using iterated mollification and multiscale analysis, and use a modified ball construction for an extension result in BV.},
url = {https://hdl.handle.net/20.500.11811/7099}
}
urn: https://nbn-resolving.org/urn:nbn:de:hbz:5n-45984,
author = {{Peter Gladbach}},
title = {A phase-field model of dislocations on parallel slip planes},
school = {Rheinische Friedrich-Wilhelms-Universität Bonn},
year = 2017,
month = mar,
note = {We expand the Peierls-Nabarro phase-field model of dislocations on one active slip plane introduced by Koslowski, Cuitiño, and Ortiz to the case of multiple parallel slip planes embedded into a homogeneous anisotropic crystal. We deduce the leading-order behavior of the energy as lattice size and slip plane spacing tend to zero. Under a logarithmic rescaling, the limit energy in the sense of Γ-convergence takes the form of a line-tension functional supported on dislocation lines featuring interactions between parallel dislocation lines in different slip planes. An optimal dislocation configuration is shown to contain a two-scale microstructure.
This is an extension of a result by Conti, Garroni, and Müller. We are able to treat anisotropic materials with possibly nonpositive interaction kernels, and obtain the leading order energy for non-dilute dislocations in a special geometry. We use the theory of functions of bounded variation, the fractional Sobolev space H1/2, and linear elasticity theory. We show some new results using iterated mollification and multiscale analysis, and use a modified ball construction for an extension result in BV.},
url = {https://hdl.handle.net/20.500.11811/7099}
}
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