From the reviews:

"The book under review ... is another book in the same direction to unify the two approaches to studying mechanical behaviour of materials but with a focus on the specific area of superplastic flow and forming. ... There are four Appendices totaling to 60 pages ... . These ... greatly enhance the usefulness of the book. The book is a welcome addition to the literature on superplasticity and is a must-read to all those who want to study, understand, research and engineer superplastic flow." (Placid Rodriguez, Transactions of the Indian Institute of Metals, April, 2003)

"The book under review develops in a systematic manner, the linkages between phenomenology and mechanics. ... the authors discuss the various constitutive equations available for superplastic flow and boundary-value problems with superplastic forming. ... the book contains four appendices that provide useful background information ... . In summary, the book is well produced, with good quality figures and equations, and it is likely to be useful for practising technologists and also at a post-graduate level in teaching/research programmes ... ." (Atul H. Chokshi, Current Science, Vol. 84 (4), 2003)

"The aim of this monograph is ... establishing the mechanics of superplasticity as a discipline in its own right. ... a rather comprehensive overview is given on the multitude of superplastics material models available, particularly focusing on technological applications, which clearly certifies the authors' competence in the field. The strength of the book is the compilation of numerous important references (621 explicitly cited) ... . There is a lot to learn from this book." (Dr. Eva Gregorová, Materials World, Vol. 10 (4), 2002)

1 Phenomenology of Superplastic Flow.- 1.1 Historical.- 1.2 Mechanical Behaviour of Superplastics.- 1.2.1 Mechanical Tests.- 1.2.2 Typical Experimental Results.- 1.2.3 Conditions for Superplastic Flow.- 1.3 Strain Rate Sensitivity of Superplastic Flow.- 1.3.1 Strain Rate Sensitivity Index, m.- 1.3.2 ‘Universal’ Superplastic Curve.- 1.3.3 Stability of Uniaxial Superplastic Flow.- 1.4 Superplasticity from the Point of View of Mechanics.- 1.4.1 On the Definition of Superplasticity.- 1.4.2 On Experimental Studies Concerning Superplasticity.- 1.4.3 On the Presentation of Results Obtained.- 1.4.4 On Some Parameters of Superplastic Flow.- 1.4.4.1 Range of Optimal Flow.- 1.4.4.2 Mechanical Threshold.- 1.4.4.3 Activation Energies.- 1.4.4.4 Structure and Mechanical Response.- 1.4.5 On Stability of Superplastic Flow.- 2 Mechanics of Solids.- 2.1 The Subject.- 2.2. Basic Concepts.- 2.2.1 Concept of a Continuum.- 2.2.2 Stress, Strain and Strain Rate States.- 2.3 General Laws and Boundary Value Problems.- 2.4 Mathematical Models of Materials.- 2.4.1 Typical Models for Describing Mechanical Behaviour.- 2.4.2 Mechanical Models/Analogues.- 2.4.3 Theories of Plasticity.- 2.4.4 Theories of Creep.- 2.4.4.1 Phenomenology of Creep.- 2.4.4.2 Internal Variable Approach.- 2.5 Experiments in Mechanics.- 2.5.1 Mechanical Tests on Materials.- 2.5.2 Influence of Testing Machine.- 3 Constitutive Equations for Superplastics.- 3.1 Basic Requirements of Constitutive Equations.- 3.2 Phenomenological Constitutive Equations.- 3.2.1 Standard Power Law.- 3.2.2 Polynomial Models.- 3.2.3. Mechanical Modelling.- 3.2.3.1 Generalised Maxwell Body.- 3.2.3.2 Generalised Bingham Body.- 3.2.3.3 Mechanical Threshold: Analyses of Karim and Murty.- 3.2.3.4 Smirnov’s Mechanical Analogue.- 3.2.3.5 Models of Murty—Banerjee and Zehr—Backofen.- 3.2.3.6 Combinations of Non-Linear Viscous Elements.- 3.2.4 Smirnov’s Model.- 3.2.5 Anelasticity.- 3.2.6 Kinks on the Load Relaxation Curves.- 3.2.7 Mechanistic Model.- 3.2.8 Activation Energies.- 3.3 Physical Constitutive Equations.- 3.3.1 Classical Models.- 3.3.2 Modern Theories.- 3.3.2.1 Model of Ghosh.- 3.3.2.2 Model of Hamilton.- 3.3.2.3 The Model of Pschenichniuk—Astanin—Kaibyshev.- 3.3.2.4 The Model of Perevezentsev et al.- 3.4 Construction of Constitutive Equations.- 3.4.1 Common Scheme.- 3.4.2 Model of Padmanabhan and Schlipf.- 3.5. Constitutive Equations in Tensor Form.- 3.5.1 Non-Uniaxial Stress—Strain States.- 3.5.2 Some Tensor Constitutive Equations.- 3.6 Material Constants from Technological Tests.- 3.6.1 Inverse Problems.- 3.6.2 Constant Pressure Forming of a Rectangular Membrane.- 3.6.3 Constant Pressure Forming of a Circular Membrane.- 3.6.4 Model of Padmanabhan and Schlipf.- 4 Boundary Value Problems in Theory of Superplastic Metalworking.- 4.1 General Formulation of the Boundary Value Problem for Metalworking Processes.- 4.1.1 Basic Concepts and Principal Equations.- 4.1.2 Initial and Boundary Conditions.- 4.1.3 Damage Accumulation.- 4.2 Model Boundary Value Problems in Mechanics of Superplasticity.- 4.2.1 Couette Flow of Superplastics.- 4.2.1.1 Newtonian Viscous Liquid.- 4.2.1.2 Shvedov—Bingham Plastic.- 4.2.1.3 Non-Linear Viscous Material.- 4.2.2 Combined Loading of a Cylindrical Rod by Axial Force and Torque.- 4.2.3 Free Bulging of Spherical and Cylindrical Shells.- 4.2.3.1 Free Forming of a Sphere.- 4.2.3.2 Free Forming of an Infinite Cylindrical Shell.- 4.3 Numerical Solving of Boundary Value Problems in Superplasticity.- 4.3.1 Features of Boundary Value Problems in Mechanics of Superplasticity.- 4.3.2 Finite Element Modelling of Superplastic Metalworking Processes.- 4.3.3 Numerical Models of Superplastic Sheet Forming Processes.- 4.3.3.1 Principal Equations of Membrane Theory.- 4.3.3.2 Numerical Solutions of the Principal Equations of Membrane Theory.- 5 Mathematical Modelling of Superplastic Metalworking Processes.- 5.1 Modelling of Superplastic Bulk Forming Processes.- 5.1.1 General Comments.- 5.1.2 Compression of a Disc using Platens.- 5.1.3 Forging of a Disc by Rotating Dies.- 5.1.3.1 Formulation of the Simplified Boundary Value Problem.- 5.1.3.2 Solving the Simplified Boundary Value Problem.- 5.1.3.3 Analysis of the Solution Obtained.- 5.1.4 Extrusion.- 5.1.5 Die-less Drawing.- 5.1.6 Roll Forming Processes.- 5.1.7 Clutching.- 5.2 Modelling of Sheet Metal Processes.- 5.2.1 Simplifications in Modelling SPF and SPF/DB Processes.- 5.2.2 Main Challenges in Modelling SPF and SPF/DB Processes.- 5.2.3 SPF of Hemispherical Domes.- 5.2.3.1 Finite Strain Behaviour.- 5.2.3.2 Jovane’s Model.- 5.2.3.3 Geometric /Kinematic Models.- 5.2.3.4 Model of Cornfield—Johnson and its Modifications.- 5.2.3.5 Holt’s Model and its Modifications.- 5.2.4 Free Forming of Spherical Vessels.- 5.2.4.1 Description of the Process.- 5.2.4.2 Mathematical Model.- 5.2.4.3 Wrinkling in Superplastic Forming.- 5.2.5 SPF of a Long Rectangular Membrane.- 5.2.5.1 Thickness Distribution.- 5.2.5.2 Pressure — Time Cycle.- 5.2.5.3 Comparison with Experimental Results.- 5.2.6 Estimating Strain in SPF and SPF/DB Processes.- 5.3 Deformation Processing of Materials.- 5.3.1 General Notes.- 5.3.2 Torsion under Pressure and ECA Extrusion.- 5.3.3 Thermomechanical Conditions for Grain Refinement.- 5.3.4 On Some Principles of Structure Refinement.- 6 Problems and Perspectives.- 6.1. Influence of Strain History on Evolution of Structure.- 6.2. Constitutive Equations Including Structural Parameters.- 6.3. The Concept of Database ‘TMT—Structure—Properties’.- 6.4. Challenges in Mechanics of Superplasticity.- 6.4.1. Experimental Superplasticity.- 6.4.2. Constitutive Equations.- Appendix A: Finite Strain Kinematics of Solids.- A.1 Basic Concepts.- A.2 Theory of Deformations.- A.2.1 Strain Tensors.- A.2.2 Geometrical Sense of Strain Tensor Components.- A.2.3 Method of Determining the Principal Components of a Strain Tensor.- A.2.4 Volumetric and Deviatoric Parts of Strain Tensors.- A.3 Strain Rate Tensor.- A.3.1 Covariant Components of Strain Tensor.- A.3.2 Distortion and Spin Tensors.- A.3.3 Strain Rate Tensor Invariants.- A.3.4 Volumetric and Deviatoric Parts of the Strain Rate Tensor.- A.3.5 On Some Scalar Characteristics of a Deformed State.- Appendix B: Kinematics of Some Simple Deformation Modes.- B.1 Tension/Compression of a Cylindrical Rod.- B.2 Simple Shear.- B.3 Pure Shear.- B.4 Bulging of a Sphere.- B.5 Finite Strain Kinematics under Combined Loading of a Cylindrical Rod by Axial Force and Torque.- Appendix C: On Dimensional Analysis.- C.1 Basic Concepts.- C.2 Viscous Flow.- C.3 Non-Newtonian Flow.- C.4 Superplastic Flow.- C.5 Dimensionless Parameters for the Boundary Value Problem of Superplasticity.- C.6 Physical Modelling of Superplastics.- Appendix D: Group Properties of Thermoviscoplasticity.- D.1 About Single-Parameter Groups of Transforms.- D.2 Applications of Group Methods in Superplasticity.- References.

The present book aims at the following: - To outline briefly the techniques of mechanics of solids, particularly as it applies to strain rate sensitive materials, - to assess the present level of investigations on the mechanical behaviour of superplastics, - to formulate the main issues and challenges in mechanics of superplasticity, - to analyse the mathematical models/constitutive equations for superplastic flow from the viewpoint of mechanics, - to review the models of superplastic metal working processes, - to indicate with examples possible new results that can be obtained using the methods of mechanics of solids. It is intended for a variety of readers who may be interested in the phenomenon of superplasticity for different reasons: materials scientists and physicists working in educational institutions and R&D units, those who wish to work on the applications of superplasticity, engineers in industry, students at senior undergraduate and postgraduate levels and those who wish to understand the phenomenology and mechanics of superplasticity without involvement in actual research. A reader who has exposure to standard differential and integral calculus and elementary tensor calculus at a level taught to senior undergraduate students at a technical university should have no difficulty in following the treatments. The analytical procedures are explained in an Appendix with simple examples.