Reprint
Crystal Plasticity at Micro- and Nano-scale Dimensions
Edited by
August 2021
322 pages
- ISBN978-3-0365-0874-0 (Hardback)
- ISBN978-3-0365-0875-7 (PDF)
This book is a reprint of the Special Issue Crystal Plasticity at Micro- and Nano-scale Dimensions that was published in
Chemistry & Materials Science
Engineering
Environmental & Earth Sciences
Summary
The present collection of articles focuses on the mechanical strength properties at micro- and nanoscale dimensions of body-centered cubic, face-centered cubic and hexagonal close-packed crystal structures. The advent of micro-pillar test specimens is shown to provide a new dimensional scale for the investigation of crystal deformation properties. The ultra-small dimensional scale at which these properties are measured is shown to approach the atomic-scale level at which model dislocation mechanics descriptions of crystal slip and deformation twinning behaviors are proposed to be operative, including the achievement of atomic force microscopic measurements of dislocation pile-up interactions with crystal grain boundaries or with hard surface coatings. A special advantage of engineering designs made at such small crystal and polycrystalline dimensions is the achievement of an approximate order-of-magnitude increase in mechanical strength levels. Reasonable extrapolation of macro-scale continuum mechanics descriptions of crystal strength properties at micro- to nano-indentation hardness measurements are demonstrated, in addition to reports on persistent slip band observations and fatigue cracking behaviors. High-entropy alloy, superalloy and energetic crystal properties are reported along with descriptions of deformation rate sensitivities, grain boundary structures, nano-cutting, void nucleation/growth micromechanics and micro-composite electrical properties.
Format
- Hardback
License
© 2022 by the authors; CC BY-NC-ND license
Keywords
crystal strength; micro-crystals; nano-crystals; nano-polycrystals; nano-wires; whiskers; pillars; dislocations; hardness; crystal size dependencies; fracture; strain rate sensitivity; temperature effect; indentation size effect; theoretical model; nano-indentation; crack growth; dislocation models; pile-ups; kitagawa-takahashi diagram; fracture mechanics; internal stresses; molecular dynamics simulations; BCC Fe nanowires; twin boundaries; de-twinning; micromechanical testing; micro-pillar; bi-crystal; discrete dislocation pile-up; grain boundary; free surface; anisotropic elasticity; crystallographic slip; molecular dynamics; nanocutting; iron; dislocations; cutting theory; ab initio calculations; hydrogen embrittlement; grain boundary; cohesive strength; multiaxial loading; strain rate; molecular dynamics simulation; strain rate sensitivity; activation volume; grain growth; indentation creep; size effect; strain rate sensitivity; activation volume; geometrically necessary dislocations; FeCrAl; micropillar; dislocation; grain boundary; strain hardening; crystal plasticity simulations; persistent slip band; surface hard coating; fatigue crack initiation; fatigue; cyclic deformation; internal stress; copper single crystal; dislocations; rafting behavior; phase-field simulation; crystal plasticity theory; mechanical property; ultrafine-grained materials; intermetallic compounds; B2 phase; strain hardening behavior; synchrotron radiation X-ray diffraction; HMX; elastic properties; molecular dynamics; linear complexions; dislocations; strength; lattice distortive transformations; dislocation emission; grain boundaries; nanomaterials; Hall-Petch relation; metals and alloys; fracture; interfacial delamination; nucleation; void formation; cracking; alloys; nanocrystalline; thermal stability; IN718 alloy; dislocation plasticity; twinning; miniaturised testing; in situ electron microscopy; magnesium; anode; tin sulfide; lithium ion battery; conversion reaction; nanoflower; rapid solidification; compression; micropillar