Classical Continuum Mechanics (2nd Ed.) Applied and Computational Mechanics Series
Auteur : Surana Karan S.
This book provides physical and mathematical foundation as well as complete derivation of the mathematical descriptions and constitutive theories for deformation of solid and fluent continua, both compressible and incompressible with clear distinction between Lagrangian and Eulerian descriptions as well as co- and contra-variant bases. Definitions of co- and contra-variant tensors and tensor calculus are introduced using curvilinear frame and then specialized for Cartesian frame. Both Galilean and non-Galilean coordinate transformations are presented and used in establishing objective tensors and objective rates. Convected time derivatives are derived using the conventional approach as well as non-Galilean transformation and their significance is illustrated in finite deformation of solid continua as well as in the case of fluent continua.
Constitutive theories are derived using entropy inequality and representation theorem. Decomposition of total deformation for solid and fluent continua into volumetric and distortional deformation is essential in providing a sound, general and rigorous framework for deriving constitutive theories. Energy methods and the principle of virtual work are demonstrated to be a small isolated subset of the calculus of variations. Differential form of the mathematical models and calculus of variations preclude energy methods and the principle of virtual work. The material in this book is developed from fundamental concepts at very basic level with gradual progression to advanced topics.
This book contains core scientific knowledge associated with mathematical concepts and theories for deforming continuous matter to prepare graduate students for fundamental and basic research in engineering and sciences. The book presents detailed and consistent derivations with clarity and is ideal for self-study.
Karan S. Surana attended undergraduate school at Birla Institute of Technology and Science (BITS), Pilani, India and received a B.E. in mechanical engineering in 1965. He then attended the University of Wisconsin, Madison where he obtained M.S. and Ph.D. in mechanical engineering in 1967 and 1970. He joined The University of Kansas, Department of Mechanical Engineering faculty where he is currently serving as Deane E. Ackers University Distinguished Professor of Mechanical Engineering. His areas of interest and expertise are computational mathematics, computational mechanics, and continuum mechanics. He is the author of over 350 research reports, conference papers, and journal papers.
Date de parution : 12-2021
15.6x23.4 cm
Thèmes de Classical Continuum Mechanics :
Mots-clés :
Continuum Mechanics; Plasticity; Covariant Basis; Contravariant Basis; Kronecker Delta; Index Notation; Permutation Tensor; Mass Density; Transport Theorem; First Law of Thermodynamics; Second Law of Thermodynamics; Balance of Linear Momenta; Vorticity Vector; Material Derivative of Determinant of J; Matrix Notation; Einstein's notation; Jacobian of Deformation; Elasticity; Constitutive Theory; Convected Time Derivatives; Entropy Inequality; Material Coefficients; Green's Strain Tensor; Eulerian Description; Argument Tensor; Heat Vector; Finite Deformation; Finite Strain; Piola Kirchhoff Stress Tensor; Lagrangian Description; Balance Laws; Dissipation Mechanism; Higher Order Global Differentiability; Strain Rates; Stress Tensor; Cauchy Stress Tensor; Entropy Generation; Strain Tensor; Deviatoric Stress Tensor; Solid Continua; Shear Thickening Fluids; Space Time Differential Operator; Real Gas Models