Novel methods for micromechanical examination of hydrogen and grain boundary effects on dislocations

Novel methods for micromechanical examination of hydrogen and grain boundary effects on dislocations

Most of what is known about the local interaction of dislocations with grain boundaries and hydrogen is based on transmission electron microscopy studies, which suffer from the distinct disadvantage that only extremely thin samples can be used. Recently, micropillar compression testing has become a...

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Bibliographic Details
Published in:Philosophical magazine (2003. Print) Vol. 92; no. 25-27; pp. 3216 - 3230
Main Authors: Kheradmand, Nousha, Dake, Jules, Barnoush, Afrooz, Vehoff, Horst
Format: Journal Article Conference Proceeding
Language:English
Published: Abingdon Taylor & Francis Group 01-09-2012
Taylor & Francis
Subjects:
bicrystal
Condensed matter: structure, mechanical and thermal properties
Defects and impurities in crystals; microstructure
dislocations
EBSD
electrochemical hydrogen embrittlement
Exact sciences and technology
FIB
Grain and twin boundaries
grain boundaries
Interaction between different crystal defects; gettering effect
Linear defects: dislocations, disclinations
mechanical properties
micropillar compression
nanoindentation
nickel
Physics
Structure of solids and liquids; crystallography
Dislocation interactions
Grain boundaries
Strengthening
Crystal defects
Deformation
Compressive testing
Mechanical properties
Dislocations
Micromechanics
Hardening
Transmission electron microscopy
Imaging
Size effect
Hydrogen embrittlement
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Summary:Most of what is known about the local interaction of dislocations with grain boundaries and hydrogen is based on transmission electron microscopy studies, which suffer from the distinct disadvantage that only extremely thin samples can be used. Recently, micropillar compression testing has become a popular means by which investigation of the size effect is conducted. This method, in combination with orientation imaging techniques, is used here to study the interaction of dislocations with a pre-selected grain boundary during the deformation of a bicrystalline specimen. Furthermore, by utilizing a custom built electrochemical cell, the micropillar compression testing can be extended to study in situ examination of micropillars charged with hydrogen. The effects of hydrogen and grain boundary on the deformation process in this small, but still bulk-like volume are presented, and our initial results reveal the value of this new technique for investigations of hydrogen embrittlement and grain boundary strengthening.
ISSN:1478-6435
1478-6443
DOI:10.1080/14786435.2012.690939