Size effects in single crystal plasticity of copper under uniaxial loading

Publikationen: Thesis / Studienabschlussarbeiten und HabilitationsschriftenDissertation

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Size effects in single crystal plasticity of copper under uniaxial loading. / Kiener, Daniel.
2007. 127 S.

Publikationen: Thesis / Studienabschlussarbeiten und HabilitationsschriftenDissertation

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@phdthesis{df93eb8229834982b2b3843ab3f4734e,
title = "Size effects in single crystal plasticity of copper under uniaxial loading",
abstract = "A new method to investigate the mechanical properties of miniaturized single crystal copper specimen was developed. Machining of these samples was accomplished using an ion beam. The limitations inherent to the method due to defect generation by ion bombardment were investigated by microstructural investigation and mechanical testing. To ensure highly precise loading along with the possibility to monitor the acting deformation mechanisms during testing at high lateral resolution, a microindenter was installed in the vacuum chamber of a scanning electron microscope. Investigations on compression specimen with different crystal orientation and geometry demonstrated the constraints present in micro-compression testing, in particular at the interface between sample and punch. Therefore, a new method was developed to perform miniaturized tensile tests. This allows the systematic study of the influence of specimen dimensions and aspect ratio on the mechanical properties without the restrictions known from compression testing. Tensile specimen with high aspect ratio depicted no hardening and a weak size dependence of the flow stress, while for short gauge lengths a dramatic rise in flow stress and significant hardening was observed. This demonstrates the influence of the interface in micro-compression testing, causing dislocations to pile-up, with the resulting back-stress on the active sources contributing to the size effect.",
keywords = "Einkristall, Plastizit{\"a}t, Gr{\"o}{\ss}eneffekte, Kupfer, Miniaturisierte Pr{\"u}fmethoden, Druckversuch, Zugversuch, single crystal, copper, plasticity, size effect, miniaturized testing methods, compression testing, tensile testing",
author = "Daniel Kiener",
note = "no embargo",
year = "2007",
language = "English",

}

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TY - BOOK

T1 - Size effects in single crystal plasticity of copper under uniaxial loading

AU - Kiener, Daniel

N1 - no embargo

PY - 2007

Y1 - 2007

N2 - A new method to investigate the mechanical properties of miniaturized single crystal copper specimen was developed. Machining of these samples was accomplished using an ion beam. The limitations inherent to the method due to defect generation by ion bombardment were investigated by microstructural investigation and mechanical testing. To ensure highly precise loading along with the possibility to monitor the acting deformation mechanisms during testing at high lateral resolution, a microindenter was installed in the vacuum chamber of a scanning electron microscope. Investigations on compression specimen with different crystal orientation and geometry demonstrated the constraints present in micro-compression testing, in particular at the interface between sample and punch. Therefore, a new method was developed to perform miniaturized tensile tests. This allows the systematic study of the influence of specimen dimensions and aspect ratio on the mechanical properties without the restrictions known from compression testing. Tensile specimen with high aspect ratio depicted no hardening and a weak size dependence of the flow stress, while for short gauge lengths a dramatic rise in flow stress and significant hardening was observed. This demonstrates the influence of the interface in micro-compression testing, causing dislocations to pile-up, with the resulting back-stress on the active sources contributing to the size effect.

AB - A new method to investigate the mechanical properties of miniaturized single crystal copper specimen was developed. Machining of these samples was accomplished using an ion beam. The limitations inherent to the method due to defect generation by ion bombardment were investigated by microstructural investigation and mechanical testing. To ensure highly precise loading along with the possibility to monitor the acting deformation mechanisms during testing at high lateral resolution, a microindenter was installed in the vacuum chamber of a scanning electron microscope. Investigations on compression specimen with different crystal orientation and geometry demonstrated the constraints present in micro-compression testing, in particular at the interface between sample and punch. Therefore, a new method was developed to perform miniaturized tensile tests. This allows the systematic study of the influence of specimen dimensions and aspect ratio on the mechanical properties without the restrictions known from compression testing. Tensile specimen with high aspect ratio depicted no hardening and a weak size dependence of the flow stress, while for short gauge lengths a dramatic rise in flow stress and significant hardening was observed. This demonstrates the influence of the interface in micro-compression testing, causing dislocations to pile-up, with the resulting back-stress on the active sources contributing to the size effect.

KW - Einkristall

KW - Plastizität

KW - Größeneffekte

KW - Kupfer

KW - Miniaturisierte Prüfmethoden

KW - Druckversuch

KW - Zugversuch

KW - single crystal

KW - copper

KW - plasticity

KW - size effect

KW - miniaturized testing methods

KW - compression testing

KW - tensile testing

M3 - Doctoral Thesis

ER -