Plastic Deformation of Nanostructured Materials
Auteurs : Glezer A.M., Kozlov E.V., Koneva N.A., Popova N. A., Kurzina I. A.
Plastic Deformation of Nanostructured Materials offers comprehensive analysis on the most important data and results in the field of materials strength and mechanics. This reference systematically examines the special features of the mechanical behavior and corresponding structural mechanisms of crystal structure defects with grain sizes that range from meso- to micro- levels.
Stages of plastic deformation of polycrystalline materials. The structure and mechanical properties of nanocrystals. Main components of the dislocation structure and the role of the dimensional factor. Dislocation structure and internal stress fields. High plastic strains. Effect of ion implantation on structural and phase states and the strength of modified metal surfaces. Grain boundary engineering and superhigh strength of nanocrystals.
A.M. Glezer, E. V. Kozlov, N. A. Koneva, N. A. Popova, I. A. Kurzina
Date de parution : 06-2020
15.6x23.4 cm
Date de parution : 08-2017
15.6x23.4 cm
Thèmes de Plastic Deformation of Nanostructured Materials :
Mots-clés :
FCC Solid Solution; Dislocation Free Grains; Ultra-fine grained and nanostructural materials; Scalar Dislocation Density; amorphous materials; ECAP; defect structure; UFG Copper; mechanical behavior; GB; grain boundary engineering; UFG Material; strain hardening; Dislocation Ensemble; A; M; Glezer; SPD; E; V; Kozlov; Internal Stress Fields; N; A; Koneva; Shear Bands; N; A; Popova; FCC Metal; I; A; Kurzina; Triple Junctions; Dislocation Density; Copper Polycrystals; Dislocation Substructures; Hall Petch Relation; Ultrafine Grained Metals; Recrystallised Grains; Amorphous Alloy; Statistically Stored Dislocations; Dynamic Recrystallisation; Work Hardening Coefficient; Polycrystalline Aggregate; Microhardness HV