Chapter 1. ABOUT THEORETICAL STRENGTH OF MATERIALS

1.1 Theoretical strength of solids

1.2 The relationship between elastic modulus and theoretical strength

1.3 The concept of phonon destruction

1.4 Phonon theory of destruction of polymer chain

1.5 The relationship between mechanical and thermal properties of solids

1.6 Types of cracks

1.7 Non-linear fracture mechanics and fracture criteria

1.8 Griffith theory of fracture of solids

Chapter 2. GENERAL LAWS OF FRICTION AND WEAR OF POLYMERS

2.1 The nature and properties of elastomer friction

2.2 Principles of failure of elastomers

2.3 Thermodynamics of failure and criticism of Griffith theory

2.5 Statistical theory of fatigue fracture

2.6 The mechanism of fatigue failure of elastomers

2.7 The principles of scaling and generalized variables

2.8 The transition to dimensionless parameters. π-theorem

2.10 The reasons of absence of self-sealing effect in elastomers

Chapter 3. FRACTAL KINETICS OF FRACTURE

3.1 The concept of fractal. Fractal dimension

3.2 Fractals of condensed matter physics

3.3 Fractal properties of hierarchical structure of potential relief

3.4 Kinetics of fracture from the point of theory of fractals

3.5 Analysis of relationship between the fractal dimension of dissipative structure of pre-destruction zone, and the mechanical properties and the critical deformation states of metals and alloys

3.6 Diagnosis of contact interaction of solids using fractal analysis method

3.6.1 The emergence of fractal structures during evolution of complex systems

3.6.2 The dependence of contour pressure roughness at elastic and plastic contacts

3.6.3 The calculation of power spectrum of profile roughness and the diagnosis of contact modes of metallic bodies

4.1 Efficient linear-viscoelastic characteristics of non-homogenous elastic (composites) and viscoelastic bodies

4.2 Derivation of expressions of new efficient moduli

4.3 Analytical solution of the problem of loading viscoelastic half-space

4.4 Building approximate solutions with effective time moduli

4.5 Modification of efficient Hashin-Shtrikman moduli for the two-component isotropic composite

4.6 Derivation of expressions of effective Hashin-Shtrikman moduli of racing type

4.7 Models of averaging effective characteristics of the two-component elastic composite

4.7.1 Model of iterative conversion of efficiency characteristics

4.7.2 Model of averaging effective characteristics

4.8 The problem of loading double-layer shell

4.9 The problem of loading triple-layer plates

4.10 Nano-tribological processes during electric discharge in discrete ohmic contacts of "polymer-metal" pairs

4.10.1 Electrical currents in surface and sub-surface layers of polymer lining

4.10.2 Electrical rift in discrete ohmic contacts of metal-polymer pairs of tribosystems

4.10.3 Local fracturing of polymer films in ohmic contacts of tribo-coupling

4.11 The frictional interaction in electric and thermal fields of metal-polymer frictional pairs

4.11.1 Electrical conductivity of surface lining of polymer lining

4.11.2 The contact-impulse interaction of frictional pairs with different energy levels of materials

4.11.3 Selection of materials of electrodes and their behavior at the transition phase of the first kind

4.11.4 The general laws of electrodynamic char
About the Author: Ahad Janahmadov is a scientist and expert in the field of tribology and triboengineering. He has authored over 350 works and was awarded several prizes, more recently the Gold Medal of the Russian Academy of Natural Sciences.