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Advances in applied mechanics /
Advances in Applied Mechanics draws together recent, significant advances in various topics in applied mechanics. Published since 1948, the book aims to provide authoritative review articles on topics in the mechanical sciences. While the book is ideal for scientists and engineers working in various...
| Clasificación: | Libro Electrónico |
|---|---|
| Autores principales: | , |
| Formato: | Electrónico eBook |
| Idioma: | Inglés |
| Publicado: |
[Amsterdam] :
Elsevier Academic Press,
2016.
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| Temas: | |
| Acceso en línea: | Texto completo |
Tabla de Contenidos:
- Front Cover; Advances in Applied Mechanics; Copyright; Contents; Contributors; Chapter One: Internal Length Gradient (ILG) Material Mechanics Across Scales and Disciplines; 1. Introduction; 1.1. Background and Motivation; 1.2. Key Concepts and Techniques; 1.3. Relevance to Emerging Science/Technology/Biomedicine Research Areas; 1.3.1. Structural NC/UFG/BMG and Micro-/Nanoheterogeneous Materials; 1.3.2. High-Energy Density Storage and Optoelectronic Materials; 1.3.3. Brain Mechanics and Neuroelasticity; 2. Methodology and Proposed ILG Platform.
- 2.1. Generic Theoretical Modeling and Numerical Issues2.2. Generic Experimental Issues and Model Validation; 3. Emerging Research Case-Study Areas; 3.1. Structural Materials: NCs/UFGs and BMGs; 3.2. Energetic Materials: LiBs/NaBs, MEMs/NEMs, and LEDS; 3.2.1. Gradient Chemomechanics and LiBs/NaBs; 3.2.2. Gradient Electromechanics: MEMS/NEMS and Interconnects; 3.2.3. Gradient Photomechanics and LEDs; 3.3. Brain ILG Mechanics and Neuroelasticity; 4. Benchmark Problems; 4.1. Gradient Chemoelasticity: Size-Dependent Damage and Phase Separation in LiBs.
- 4.1.1. LiB Anodes and Size-Dependent Chemomechanical Damage4.1.2. LiB Cathodes and Size-Dependent Phase Transformations; 4.2. Gradient Electroelasticity and Size Effects; 4.2.1. Gradient Piezoelectric Perforated Plate Under Shear; 4.2.2. Gradient Piezoelectric Beam with Flexoelectric and Surface Effects; 4.3. Gradient Elastic Fracture Mechanics; 4.3.1. GradEla Nonsingular Crack Fields; 4.3.2. Dislocation-Based Gradient Elastic Fracture Mechanics; 4.4. Gradient Plasticity and Shear Instabilities: Size-Dependent Stability Diagrams; 4.4.1. Shear Bands in BMGs for Infinite Domains.
- 4.4.2. Finite Domains and Size Effects4.5. Combined Gradient-Stochastic Models and Size Effects in Micro-/Nanopillars; 4.5.1. Stochasticity-Enhanced Gradient Plasticity Model; 4.5.2. Analysis of Heterogeneity and Size Dependence Through Tsallis q-Statistics; 4.6. Further Considerations on Tsallis q-Statistics; 4.6.1. Tsallis q-Statistics for Serrations; 4.6.2. Image Analysis of Multiple Shear Bands; 4.7. Fractional Calculus and Fractal Media; 4.7.1. Fractional Gradient Elasticity and Fractal Elasticity; 4.7.2. Fractional Gradient Plasticity and Fractal Plasticity; 5. Concluding Remarks.
- 5.1. Generalized Continuum Mechanics Aspects5.2. Extensions Beyond Nanotechnology; 5.3. Extensions to Biomedicine; Acknowledgments; References; Chapter Two: Scaling to RVE in Random Media; 1. Micro-, Meso-, and Macroscales; 1.1. Random Microstructure and RVE; 1.2. RVE via Hill-Mandel Condition; 1.3. Hierarchy of Mesoscale Bounds; 2. Spatial Randomness; 2.1. Tensor Random Fields in Stochastic Mechanics; 2.2. Ergodicity in Mean and in Covariance; 2.3. Stochastic Boundary Value Problems; 3. Antiplane Elasticity = In-Plane Conductivity; 3.1. Hierarchies of Mesoscale Bounds; 3.2. Scaling Function.