Cover; Title; Copyrights; Preface; Contents; Notations; 1. Introduction and Overview; 1.1 Definition of structured composites and nanomaterials; 1.1.1 The use of nanocomposites in space technology; 1.1.2 Classification of polymers ordinary solid bodies?; 1.2 What is the main difference between the composites and; 1.3 Composite structural systems; 1.3.1 Classification according to a structured feature; 1.3.2 Reinforced media theory; 1.4 Model of elastic deformation of a unidirectional multilayered composite material; 1.4.1 Elastic deformation model of cross-reinforced composite material
1.5 Optimization of multi-layered composite structure parameters1.5.1 Influence of fiber length; 1.5.2 Elastic behavior-longitudinal loading; 1.6 Molecular mechanisms of chemical reactions; 1.6.1 Chemical reaction kinetics; 1.6.2 Methods for determining the order of reactions; 1.6.3 Ostwald's "isolation method"; 1.6.4 Graphic method; 1.6.5 The differential method of Van't Hoff; 1.6.6 Dependence of the reaction rate on temperature; References; 2. Creep Laws for Composite Materials; 2.1 Introduction; 2.2 Phenomenological creep model: single integral type constitutive equation (CE)
3.2 Brief classification of non-newtonian fluids3.3 Composite design process; 3.3.1 Artificial composite materials; 3.4 Mechanical testing of composites; 3.5 Resilient properties of composites; 3.6 The phenomenological approach in mechanics of heterogeneous media; 3.6.1 Structured-phenomenological approach to the solution of boundary value mechanics of composites; 3.6.2 Equilibrium equations of multilayered composites; 3.6.3 Hooke's law for each layer; 3.6.4 Elastic deformation model of cross-reinforced composite material; 3.7 Phenomenological creep models of composite structures
3.8 Temperature-time dependent structured heterogeneous composites3.9 General form of Equation (3.37); 3.10 Phenomenological creep models of composites with dispersed filler; References; 4. Creep Models of Nanocomposites: Deterministic Approach; 4.1 Introduction; 4.1.1 Small scaled materials; 4.1.2 Approaches to larger surface area; 4.1.3 Size effect and the nanomaterials properties; 4.2 Physical aspects of nanocomposite structures; 4.3 Chemical aspects of nanocomposite structures and reaction kinetics; 4.3.1 Rate of reaction; 4.3.2 Integrated rate laws
Notes
4.3.3 Dependence of the conversion of metal ions on time
