Lectures related to Anisotropic Elastic Materials

Elasticity: Stiffness and Compliance Tensors

Covers stiffness and compliance tensors, Hooke's law, stress-strain relations, and material symmetries.

Covers anisotropic elasticity with examples of materials having varying properties in different directions.

Anisotropic Elasticity 2: Symmetry Operations, Multiphysics

Covers anisotropic elasticity, symmetry operations, and multiphysics in material science.

Linear Elasticity: Equations of Linear Elasticity

Covers the equations of linear elasticity for static problems with small strain, emphasizing uniqueness of solutions and Navier's Equations.

Laminate Analysis: Introduction

Introduces the theory behind laminates and their applications in different industries.

Elasticity: Hooke's Law

Covers Hooke's Law in elasticity, discussing stiffness and compliance tensors.

Linear Elasticity in 3D: Beam Bending

Covers linear elasticity in 3D, focusing on beam bending and stress-strain behavior of materials.

Rigorous Bounds: Isotropic Phases

Explores rigorous upper and lower bounds for isotropic phase composites and their microstructure arrangement, focusing on laminated plates and stress-strain relationships.

Elasticity and Deformation

Covers stress, strain, modulus of elasticity, and material behavior under different loads.

Linear Elasticity: Cylindrically-symmetric Problems

Covers linear elasticity, focusing on cylindrically-symmetric problems and the simplification of Hooke's Law for axially-symmetric cases.

Structural Mechanics: Beam Bending and Boundary Conditions

Explores the moment-curvature relation for beams, emphasizing stress distribution and typical boundary conditions.

Stress and Deformation: Understanding Material Behavior

Explores stress, strain, elasticity, plasticity, and material behavior, emphasizing the importance of dislocations and microstructure.

Linear Elasticity: Channel Die Compression with Friction

Explores linear elasticity in confined compression with friction and stress distributions.

Eshelby Method: Modulus Mismatch and Eigenstrains

Discusses stress concentrations, modulus mismatch, and eigenstrains in materials.

Linear Elasticity: Basics and Material Functions

Introduces the basics of linear elasticity, material functions, and stress-strain relationships in isotropic materials.

Anisotropic Elasticity: Stroh Formulation

Explores the Stroh formulation for anisotropic elasticity and issues with current solution techniques.

Solid Mechanics Principles: Greens Functions

Explores Greens functions in solid mechanics, emphasizing the solution of point forces and their impact on displacement fields.

Deformation of Materials: Stresses, Deformations, and Elasticity

Explores the deformation of materials through stresses, deformations, and elasticity, focusing on the behavior of metals, ceramics, and polymers.

Axial Loading: Stress and Strain in Deformable Bodies

Covers axial loading, stress, strain, and their implications in deformable bodies.

Elasticity and Beam Bending

Explores linear elasticity, stress-strain relationships, and beam bending kinematics with a focus on stress tensors and internal forces.