Autowave plasticity : localization and collective modes /

Autowave Plasticity: Localization and Collective Modes discusses the nature of plastic flow in solids associated with the development of a localized plastic flow. Written by an authority in the field, the author demonstrates how patterns of localized plastic flow are associated with autowave modes t...

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Bibliographic Details
Main Author:	Zuev, Lev (Author)
Corporate Author:	Taylor & Francis
Other Authors:	Riecansky, V. E. (Translator)
Format:	eBook
Language:	English
Published:	Boca Raton, FL : CRC Press, [2021]
Subjects:	Plasticity. Plastics > Viscosity. Plasticité. Matières plastiques > Viscosité. plasticity. TECHNOLOGY > Material Science. SCIENCE > Solid State Physics. Plasticity Electronic books.
Online Access:	Connect to the full text of this electronic book

Table of Contents:

Cover
Half Title
Title Page
Copyright Page
Table of Contents
Preface
Introduction
1. Plastic flow. Important regularities
1.1. Multi-scale plastic flow heterogeneity
1.1.1. Dislocation level of deformation
1.1.2. Mesoscale strain level
1.1.3. Macrostrain scale level
1.1.4. Lattice scale level
1.1.5. Temporal nonuniformity of plastic flow
1.2. Models of different-scale processes of plastic flow
1.2.1. Dislocation models
1.2.2. Large-scale distribution of strain
1.3. Plastic deformation as self-organization
1.3.1. On the possibilities of synergetics in the theory of plasticity
1.3.2. On collective phenomena in plasticity
1.4. Plasticity problem
1.4.1. Localization and the self-organization of plastic flow
1.4.2. On the principles of constructing a model of plastic flow
2. Macroscopic localization of plastic flows
2.1. Methods of observing patterns of localized plasticity
2.1.1. ALMEC complex. Principle of operation
2.1.2. ALMEC-tv complex. Principle of operation
2.2. Patterns of localized plasticity
2.2.1. Patterns of localized plasticity and general deformation
2.2.2. Patterns of localized plasticity. Qualitative analysis
2.2.3. Patterns of localized plasticity. Quantitative analysis
2.2.4. Kinetics of development of patterns
2.3. On the choice of materials for research
2.4. Stage of plastic deformation and localization patterns
2.4.1. Selection of stages of the plastic flow curve
2.4.2. The yield plateau stage
2.4.3. Stages of easy slip and linear hardening
2.4.4. Stage of parabolic hardening
2.4.5. Pre-fracture stage
2.5. The evolution of localization patterns during interstage transitions
2.5.1. Transition patterns
2.5.2. Compliance Rule
3. Plastic flow as an autowave process.
3.1. Localization as self-organization of plastic flow
3.1.1. Actual properties of plastically deformable media
3.1.2. Hypothesis about the autowave character of localized deformation
3.1.3. Entropy of wave and autowave deformation processes
3.2. Autowave plastic flow equations
3.2.1. On the structure of autowave equations
3.2.2. Equations of autowaves of localized plastic flow
3.2.3. Analysis of autowave equations
3.3. Generation of autowave plastic deformation modes
3.3.1. Autowave generation by stress concentrators
3.3.2. Autowave modes of localization of plastic flow
3.3.3. Deformation as an evolution of autowave structure
3.4. The main characteristics of localized deformation autowaves
3.4.1. The speed of propagation of autowaves
3.4.2. Dispersion of autowaves
3.4.3. Scale effect with strain localization
3.4.4. Autowave parameters and material structure
4. Two-component plastic flow model
4.1. On the principles of plastic flow model construction
4.2. Construction of a two-component plasticity model
4.2.1. Two-component model: structure and operation
4.2.2. Numerical estimates of the capabilities of the model
4.3. The basic equation of the model
the elastoplastic invariant
4.3.1. Introduction of an elastoplastic strain invariant
4.3.2. Elastoplastic invariant and characteristics of the medium
4.3.3. On the nature of the elastoplastic deformation invariant
4.4. Implications of the two-component model
4.4.1. Phase autowave propagation speed
4.4.2. Dispersion of phase localized deformation autowaves
4.4.3. Constants in the dispersion relation for autowaves
4.4.4. Connection of the autowave length with the grain size in a polycrystal
4.4.5. Scale effect for autowave localized plasticity
4.4.6. Autowave equation of localized plasticity.
4.4.7. Autowaves and the Taylor-Orowan dislocation kinetics equation
4.4.8. The reason for generating autowaves
4.4.9. Evaluation of linear strain hardening coefficient
4.4.10. Elastoplastic invariant and Hall-Petch relation
4.4.11. Connection of elastic and plastic components of deformation
4.4.12. On the relationship of dislocation and mesoscopic scales.
4.4.13. Density of mobile dislocations
4.5. Generalization of the two-component plasticity model
5. A quasiparticle approach in plasticity physics
5.1. On the use of quantum-mechanical ideas in the physics of plasticity
5.2. Mass associated with autowave localized deformation
5.3. Introduction of quasiparticles
autolocalizon
5.4. Quasiparticle representation of localized deformation
5.4.1. Jump-like plastic deformation
5.4.2. Autowave length
autolocalizon displacement length
5.4.3. Elastoplastic deformation invariant and autolocalizon
5.5. Spectrum of elementary excitations of a deformable medium
5.5.1. Hybridization of the spectra of an elastically and plastically deformable medium
5.5.2. Dispersion and effective mass of autolocalizon
5.5.3. Condensation of quasiparticles in the process of plastic flow
5.5.4. The general meaning of the introduction of autolocalizon
5.5.5. Plasticity as a macroscopic quantum phenomenon
5.6. Deformation localization and periodic table of elements
5.6.1. General characteristics of the problem
5.6.2. Experimental data
5.6.3. Interpretation of the data
Conclusion
Bibliography
Index.