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Slip in directionally solidified Mo-alloy micropillars - Part I: Nominally dislocation-free pillars
Résumé
In situ Laue analysis during microcompression reveals plasticity in [0 0 1]-oriented, directionally solidified Mo alloy pillars to start with slip on the {1 1 2} < 1 1 1 > system having the highest Schmid factor followed by slip on the (1 1 0) plane containing the same Burgers vector. The results are interpreted in terms of the microstructure analyzed by scanning transmission electron microscopy and 3-D atom probe. (C) 2012 Acta Materialia Inc. Published by Elsevier Ltd. All rights reserved.
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Proximité ontologique
Concepts associés (14)
Burgers vector
In materials science, the Burgers vector, named after Dutch physicist Jan Burgers, is a vector, often denoted as b, that represents the magnitude and direction of the lattice distortion resulting from a dislocation in a crystal lattice. The vector's magnitude and direction is best understood when the dislocation-bearing crystal structure is first visualized without the dislocation, that is, the perfect crystal structure.
Microscopie électronique en transmission
vignette|upright=1.5|Principe de fonctionnement du microscope électronique en transmission. vignette|Un microscope électronique en transmission (1976). La microscopie électronique en transmission (MET, ou TEM pour l'anglais transmission electron microscopy) est une technique de microscopie où un faisceau d'électrons est « transmis » à travers un échantillon très mince. Les effets d'interaction entre les électrons et l'échantillon donnent naissance à une image, dont la résolution peut atteindre 0,08 nanomètre (voire ).
Microscope électronique
thumb|Microscope électronique construit par Ernst Ruska en 1933.thumb|Collection de microscopes électroniques anciens (National Museum of Health & Medicine). Un microscope électronique (ME) est un type de microscope qui utilise un faisceau d'électrons pour illuminer un échantillon et en créer une très agrandie. Il est inventé en 1931 par des ingénieurs allemands. Les microscopes électroniques ont un pouvoir de résolution supérieur aux microscopes optiques qui utilisent des rayonnements électromagnétiques visibles.
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