Continuum Thermodynamics

The following sections are included:

• Dedication
• Preface
• Contents

The intention by writing Part II of the book on continuum thermodynamics was the deepening of some issues covered in Part I as well as a development of certain skills in dealing with practical problems of macroscopic processes. However, the main motivation for this part is the presentation of main facets of thermodynamics which appear when interdisciplinary problems are considered. There are many monographs on the subjects of solid mechanics and thermomechanics, on fluid mechanics and on coupled fields but most of them cover only special problems in great details which are characteristic for the chosen field. It is rather seldom that relations between these fields are discussed. This concerns, for instance, large deformations of the skeleton of porous materials with diffusion (e.g. lungs), couplings of deformable particles with the fluid motion in suspensions, couplings of adsorption processes and chemical reactions in immiscible mixtures with diffusion, various multi-component aspects of the motion, e.g. of avalanches, such as segregation processes, etc…

The following sections are included:

• Summary: Geometry
  • Configurations
  • Deformation gradient
  • Measures of deformation
  • Polar decomposition
  • Homogeneous deformations
• Universal solutions
  • Families of universal solutions and corresponding geometric quantities
    • Family 0: Homogeneous plane deformations
    • Family 1: Bending, stretching and shearing of a rectangular block
    • Family 2: Straightening, stretching and shearing of a sector of a circular-cylindrical tube
    • Family 3: Inflation, eversion, bending, torsion, extension, and shearing of an annular wedge
    • Family 4: Inflation or eversion of a sector of a spherical shell
    • Family 5: Inflation, stretching and shearing of a circular cylinder
• A few examples of universal deformations
  • Isochoric extension
  • Simple shear
  • Pure torsion of a circular cylinder

The following sections are included:

• Summary: Kinematics of one-component media
• Two-component materials with the skeleton as reference
  • Example clarifying the Lagrangian description of relative motion

The quantities introduced in the last chapter could be deduced from the function of motion f. The form of this function has to be found for a chosen system as a solution of the governing equations, i.e., the unknown fields must be determined as functions of X and t (Lagrangian description). To this aim one has to find a set of field equations which describes the desired problem and which is fulfilled by the set of fields. The field equations are based on balance equations which in contrast to the field equations not yet include material properties. By insertion of constitutive relations, the system of balance equations changes into a system of field equations which has to be solved using appropriate initial and boundary conditions…

The following sections are included:

• Preliminaries
• D’Alembert paradox
• Fluids
  • Ideal fluids
  • Viscous fluids
    • Navier-Stokes equation, uniqueness of solutions
    • Lamellar flows
    • Creeping flows
    • Boundary layers
  • Maxwell and N-th grade (Rivlin-Ericksen) fluids; viscometric flows
    • Preliminaries
    • Viscometric flows
• Nonlinear elastic solids
  • Rubber-like materials
    • Homogeneous deformations
    • Heterogeneous deformations
• Viscoelastic solids
  • Differential constitutive relations
  • Steady state processes and elastic-viscoelastic correspondence principle

The following sections are included:

• Preliminaries
• Stability of the torsional Couette flow
• Thermal instability of a layer of fluid heated from below – Rayleigh-Bénard problem
• Stability of a nonlinear elastic strip
• Stability of the thermodynamical equilibrium of second-grade fluids

In correspondence to Chapters 5 and 6 of Part I in which thermodynamical foundations are presented, in this chapter we discuss a few applications of the theory.

Almost simultaneously with the development of extended thermodynamics, initiated by Ingo Müller, I-Shih Liu and Tommaso Ruggeri whose outline we presented in Part I, a new branch of non-equilibrium thermodynamics also called extended thermodynamics started to develop with works of David Jou, José Casas-Vázquez and Georgy Lebon. In both approaches the main idea was the extension of the number of fields but the microscopic motivation and, consequently, the structure of the macroscopic models was different. Ingo Müller and coworkers were mainly motivated by Grad’s method of the kinetic theory in which the construction of an approximate solution of Boltzmann’s equation was proposed in the form of an expansion with respect to polynomials. This hierarchic microscopic model could be easily replaced by a similar macroscopic model as it was done, for instance, in the first paper of this version of extended thermodynamics of I-Shih Liu and Ingo Müller [235]. It has been shown later that in the case of ideal gases both approaches practically coincide (compare Part I). On the other hand David Jou, José Casas-Vázquez and Georgy Lebon were primarily motivated by the non-equilibrium statistical mechanics and, in particular, by the so-called Fluctuation-Dissipation Theorem. In Section 8.3 we will comment on the main differences between this version of extended thermodynamics and that of Müller/Liu/Ruggeri, as well as their common points…

The following sections are included:

• Introduction
• Continuum with dislocations
• On plasticity of metals
• Dislocations in geophysics

The following sections are included:

• Preliminaries
• Propagation of acoustic waves in nonlinear materials with memory
• Bulk waves in nonlinear elasticity
  • Modicum of the wave front description
  • An approximate solution in the vicinity of the front
• Water waves and surface waves in linear solids
  • Introduction
  • Water waves in an ideal incompressible fluid model
  • Surface waves in linear elastic solids
    • Plane boundaries of linear elastic homogeneous materials
    • Rayleigh waves on cylindrical boundaries
  • Waves in a layer of an ideal fluid and Love waves on plane boundaries
    • Layer of a compressible fluid on a semiinfinite rigid body
    • Love waves on plane boundaries
  • Rayleigh waves in a layer of elastic material
  • Stoneley waves
    • Interface of two semiinfinite elastic solids
    • Semiinfinite elastic solid and semiinfinite ideal fluid
    • Semiinfinite elastic solid and a layer of an ideal fluid
• A few remarks on leaky waves
• Bulk and surface waves in viscoelastic solids

The following sections are included:

• Preliminaries
• Primer of Maxwell theory of electromagnetism
  • Governing equations
  • Lorentz invariance of the Maxwell equations
• On thermodynamics of coupled fields
• Magnetohydrodynamics of plasmas
  • Phenomenology
  • Characteristic parameters
  • MHD-model derived from the theory of miscible mixtures
  • Two-component model
• Magnetohydrodynamics of a single component fluid
  • Dimensionless notation, approximations
  • Some steady state flows
    • Poiseuille-Hartmann flow
    • Couette flow
• A few remarks on the stability of plasmas
  • Linear stability analysis of the ideal plasma model
  • A few particular cases of instabilities

The following sections are included:

• Summary of two-component models
  • Immiscible mixtures
  • Lagrangian description of multi-component porous media
  • Eulerian description of multi-component porous media
• Two-component models with constitutive relations for the porosity
  • Fields and field equations
  • Thermodynamic admissibility
    • Second law of thermodynamics
    • C⁽¹⁾-models
    • C⁽²⁾-models
• Double- and multi-porosity models
  • Fissured rocks – example of a model with double porosity
    • Basic physical concepts
    • Equation of motion of a uniform liquid in fissured rocks
    • Homogeneous liquid in a medium with double porosity
    • Non-steady-state flow of liquid in a gallery
  • Multi-porosity models in bioengineering – swelling media
    • Cardiovascular disease
    • Swelling
• Biomechanics of soft tissues
  • Structure of soft tissues – collagen and elastin
  • General mechanical characteristic of soft tissues
  • Model
  • Example: A model for the artery
  • Material parameters, numerical analysis and results

In the '90s Krzysztof Wilmanski introduced a model for the description of multi-component porous media with the porosity as a field and with an own balance equation (see e.g. Chapter 13 of Part I or the simplified version for saturated porous media in Subsection 13.1.2 of this book). Since this time the model has been used for several applications (diffusion processes, wave propagation, adsorption, piping and other problems). Some fields of application have already been shown in Part I, others will be shown in this section. But before, shortly the derivation of the balance equation of porosity and the model are shown (for details see Part I). Originally, it is a nonlinear, multi-component thermodynamic model. However, for applications it is mostly sufficient to consider simplified linearized versions for a small number of components, with common constant temperature for all components and without considering the gradient of porosity (then the model is called Simple Mixture Model instead of Full Model). In the following only these linearized versions of the model are revisited.

The following sections are included:

• Appendix A: Basic notions
  • Mathematical basics shown on the example of polar decomposition
  • Curvilinear coordinate systems
    • General considerations
    • Cylindrical coordinates
    • Spherical coordinates
    • Ellipsoidal coordinates
      • Confocal ellipsoidal coordinates
      • Elliptic cylindrical coordinates
    • Paraboloidal coordinates
      • Confocal paraboloidal coordinates
      • Parabolic coordinates
      • Parabolic cylindrical coordinates
    • Bipolar coordinates
    • Toroidal coordinates
    • Non-orthogonal coordinates
• Appendix B: Integral transforms
  • Fourier transforms
  • Laplace transforms
• Appendix C: Green functions
  • Purpose
  • Statics of isotropic elastic materials
  • Dynamical Green function for isotropic elastic materials
  • Some fundamental solutions for poroelastic and thermoelastic materials
• Appendix D: Bessel functions and Bessel equation
• Appendix E: Basic physical units
• Bibliography
• Index of Researchers
• Subject Index