Reprint

Crystal Plasticity (Volume II)

Edited by
January 2023
424 pages
  • ISBN978-3-0365-6287-2 (Hardback)
  • ISBN978-3-0365-6288-9 (PDF)

This book is a reprint of the Special Issue Crystal Plasticity (Volume II) that was published in

Chemistry & Materials Science
Engineering
Environmental & Earth Sciences
Summary

With the second volume, we continue our mission to providing theoretical and experimental research that contribute new insights and practical findings in the field of crystal plasticity-related topics.

Once again, a completely new set of 26 original works (including 22 research articles, 3 communications, and 1 review) has been collected. As in the case of the first volume, here, a full spectrum of topics belonging to the field of crystal plasticity is represented, including both numerical simulations and experimental works.

By taking into account the investigated materials, the papers can be assigned to the following thematic groups:

  • Steels and iron-based alloys;
  • Non-ferrous alloys with fcc- (Ni- and Cu-based), or hcp crystal structure (Mg- and Ti-based). Other examples include Zirconium, Bi-Sn alloy, or polycarbonate resins;
  • Multicomponent and high-entropy alloys;
  • General theoretical studies on crystal plasticity.

Specifically, the reprint should be interesting for students of material science and engineering, Ph.D. candidates, and researchers dealing with various theoretical and practical aspects of plastic deformation in crystalline materials.

Format
  • Hardback
License
© by the authors
Keywords
aluminum; nickel; superalloys; γ′- and γ-phases; close-packed phases; rhenium; ultra-thin grain-oriented silicon steel (UTGO); cold rolling; twinning; Goss; {100}<011>; Ti2AlNb alloy; mechanical properties; constitutive relation; Johnson–Cook model; grain boundary; crystallographic orientation; crystallographic plasticity; deformation behavior; Mg-based alloy; first principles; structural properties; tensile properties; high purity titanium; FCC phase; TKD; pole figure; transformation matrix; Bi–Sn alloy; microhardness; self-annealing; superplasticity; tube high-pressure shearing; shape memory alloys; FeNiCoAlTiNb; microstructure; shape memory effect; martensitic transformation; brass-type shear band; twin–matrix lamellae; coplanar slip; Taylor model; Cu–Zn alloy; cold-rolling texture; X-ray diffraction; zirconium; strain-gradient crystal plasticity; slip band; geometrically necessary dislocation; statistically stored dislocation; high angular resolution electron back scatter diffraction; crystal plasticity; multilevel models; large strain; motion decomposition; constitutive law; anisotropic materials; corotational derivative; strain rate; temperature; polycrystalline Cu6Sn5; molecular dynamic; tensile properties; ECAP; copper alloy; strain homogeneity; 3D FEM; thermodynamic modeling; magnesium; phase diagram; liquidus projection; nickel-based superalloy; anisotropy; slip system modelling; Schmid factor; Young’s moduli; dual-phase steel; forming limit diagrams; crystal plasticity; DAMASK; M-K approach; Keeler-Brazier approach; different grades; RSD; simulate r egression models; processing and parameters; analysis of variance; resin pigment blends; laser weld; heat input; cooling rate; residual stresses; fusion zone; meso scale; coupled temperature-displacement; dislocations; diffusion; FeC alloy; dynamic strain aging; superelasticity; FeNiCoAlTi; shape memory alloys; multi-scale modeling; dislocations; gradient materials; 21-4N valve steel; mechanical alloying; vacuum hot pressing; powder metallurgy; slip; mechanical twinning; constitutive modeling; finite element simulations; deformation behavior; twin volume fraction; plastic deformation; low-cycle fatigue; mechanical properties; pre-damage; low alloy steel; coupling damage; nickel-free austenitic stainless steel; phase transition; mechanical alloying; X-ray diffraction; profile analysis; whole powder pattern modeling; Nano (Ti,Cr)C powder; mechanical alloying (MA); nanostructure; X-ray diffraction; n/a