Reprint
Crystal Plasticity
Edited by
April 2021
438 pages
- ISBN978-3-0365-0838-2 (Hardback)
- ISBN978-3-0365-0839-9 (PDF)
This book is a reprint of the Special Issue Crystal Plasticity that was published in
Chemistry & Materials Science
Engineering
Environmental & Earth Sciences
Summary
The book presents a collection of 25 original papers (including one review paper) on state-of-the art achievements in the theory and practice of crystals plasticity. The articles cover a wide scope of research on materials behavior subjected to external loadings, starting from atomic-scale simulations, and a new methodological aspect, to experiments on a structure and mechanical response upon a large-scale processing. Thus, a presented contribution of researchers from 18 different countries can be virtually divided into three groups, namely (i) “modelling and simulation”; (ii) “methodological aspects”; and (iii) “experiments on process/structure/properties relationship”. Furthermore, a large variety of materials are investigated including more conventional (steels, copper, titanium, nickel, aluminum, and magnesium alloys) and advanced ones (composites or high entropy alloys). The book should be interested for senior students, researchers and engineers working within discipline of materials science and solid state physics of crystalline materials.
Format
- Hardback
License
© 2022 by the authors; CC BY-NC-ND license
Keywords
AZ31-Ca magnesium alloy; plasticity; slip systems; EBSD; VPSC; microstructure; texture; dislocation reactions; single crystal Ni-base superalloys; shear creep testing; transmission electron microscopy; nucleation of planar fault ribbons; high strain rate; Hall–Petch relation; Taylor–Quinney coefficient; transitional viscoplasticity; ductile damage; OFHC copper; deformable discrete element method; TRIP Steel; zirconia composite; numerical simulation; crystal plasticity; local deformation behavior; curing age; HVFANS concrete; SHPB test; DIF; toughness; critical damage; density functional theory; phase diagram; high-entropy alloy; mechanical and thermal properties; transformation diagrams; 100Cr6 steel; dilatometric test; high-entropy alloy; high-pressure torsion; microstructure; texture; phase transformation; strength; deformation behavior; warm deformation; texture; microstructure; dynamic recrystallization; processing map; BCC structure; reaction stress (RS) model; rolling; texture; orientation; titanium; Ti-13Nb-13Zr; aging; microstructure; tensile properties; Young’s modulus; local deformation; plastic deformation; grained structure; grain shape; grain surface area; degree of grain orientation; deformation tensor; AISI 420; crystal plasticity; representative volume element; VPSC; DAMASK; crystal plasticity; multilevel statistical constitutive model; grain boundary sliding; superplasticity; 1420 alloy; brittle fracture; prestrain direction; strain gradient plasticity; critical stress; dislocation density; additive manufacturing; fatigue crack initiation; crystal plasticity; finite element model; metal; biomedical materials; magnesium alloys; equal-channel angular pressing (ECAP); microstructure; X-ray diffraction (XRD); texture; mechanical properties; biodegradation; dislocation plasticity; ceramics; SrTiO3; nanoindentation; bulk deformation; crystal plasticity; DAMASK; representative volume element; dual-phase steel; local deformation behavior; dual-phase steel; martensite; hole expansion ratio; stretch flangeability; normal anisotropy; crystal plasticity; yield surface; slip systems; deformation; dislocation; dispersion hardening; nanoparticles; stress; strain; plastic deformation; tube; heat exchange; temperature; porosity; HIP; superalloys; crystal plasticity; additive manufacturing; alloy; microcompression test; precipitation strengthening; work hardening; deformation; crystal plasticity; dislocation slip; phenomenological model; physics-based model; n/a