Fundamentals of Micromechanics of Solids
Fundamentals of Micromechanics of Solids is the first book integrating various approaches in micromechanics into a unified mathematical framework, complete with coverage of both linear and nonlinear behaviors. Based on this unified framework, results from the authors' own research, as well as existing results in the literature are re-derived in a logical, pedagogical, and understandable approach. It enables readers to follow the various developments of micromechanics theories and quickly understand its wide range of applications of micromechanics.
This helpful guide is a powerful tool for learning the most fundamental ideas and approaches, basic concepts, principles, and methodologies of micromechanics. Readers will find:
* Vigorous derivations of the mathematical framework
* Introductions to both linear and nonlinear material behavior
* Unique coverage of brittle damage, shape memory alloys, and TRIP steels
* Large numbers of problems and exercises to support teaching and learning the concepts
* Lists of references and suggested readings in each chapter
1.1 Background and Motivation.
1.3 Organization of Book.
1.4 Notation Conventions.
2 Basic Equations of Continuum Mechanics.
2.1 Displacement and Deformation.
2.2 Stresses and Equilibrium.
2.3 Energy, Work, and Thermodynamic Potentials.
2.4 Constitutive Laws.
2.5 Boundary Value Problems for Small-Strain Linear Elasticity.
2.6 Integral Representations of Elasticity Solutions.
3.1 Definition of Eigenstrains.
3.2 Some Examples of Eigenstrains.
3.3 General Solutions of Eigenstrain Problems.
4 Inclusions and Inhomogeneities.
4.1 Definitions of Inclusions and Inhomogeneities.
4.2 Interface Conditions.
4.3 Ellipsoidal Inclusion with Uniform Eigenstrains (Eshelby Solution).
4.4 Ellipsoidal Inhomogeneities.
4.5 Inhomogeneous Inhomogeneities.
5 Definitions of Effective Moduli of Heterogeneous Materials.
5.1 Heterogeneity and Length Scales.
5.2 Representative Volume Element.
5.3 Random Media.
5.4 Macroscopic Averages.
5.5 Hill’s Lemma.
5.6 Definitions of Effective Modulus of Heterogeneous Media.
5.7 Concentration Tensors and Effective Properties.
6 Bounds for Effective Moduli.
6.1 Classical Variational Theorems in Linear Elasticity.
6.2 Voigt Upper Bound and Reuss Lower Bound.
6.3 Extensions of Classical Variational Principles.
6.4 Hashin–Shtrikman Bounds.
7 Determination of Effective Moduli.
7.1 Basic Ideas of Micromechanics for Effective Properties.
7.2 Eshelby Method.
7.3 Mori–Tanaka Method.
7.4 Self-Consistent Methods for Composite Materials.
7.5 Self-Consistent Methods for Polycrystalline Materials.
7.6 Differential Schemes.
7.7 Comparison of Different Methods.
8 Determination of the Effective Moduli—Multiinclusion Approaches.
8.1 Composite-Sphere Model.
8.2 Three-Phase Model.
8.3 Four-Phase Model.
8.4 Multicoated Inclusion Problem.
9 Effective Properties of Fiber-Reinforced Composite Laminates.
9.1 Unidirectional Fiber-Reinforced Composites.
9.2 Effective Properties of Multilayer Composites.
9.3 Effective Properties of a Lamina.
9.4 Effective Properties of a Laminated Composite Plate.
10 Brittle Damage and Failure of Engineering Composites.
10.1 Imperfect Interfaces.
10.2 Fiber Bridging.
10.3 Transverse Matrix Cracks.
11 Mean Field Theory for Nonlinear Behavior.
11.1 Eshelby’s Solution and Kro¨ner’s Model.
11.3 Time-Dependent Behavior of Polycrystalline Materials: Secant Approach.
12 Nonlinear Properties of Composites Materials: Thermodynamic Approaches.
12.1 Nonlinear Behavior of Constituents.
12.2 Effective Potentials.
12.3 The Secant Approach.
13 Micromechanics of Martensitic Transformation in Solids.
13.1 Phase Transformation Mechanisms at Different Scales.
13.2 Application: Thermodynamic Forces and Constitutive Equations for Single Crystals.
13.3 Overall Behavior of Polycrystalline Materials with Phase Transformation.
Mohammed Cherkaoui, Phd, is a professor in the G. W. Woodruff School of Mechanical Engineering at Georgia Institute of Technology in Atlanta. He is formerly with the Université de Metz, France.