Lectures related to Classical Laminate Theory: Analysis & Equilibrium

Classical Laminate Theory

Covers Classical Laminate Theory for solving mechanics problems with multiple material layers, discussing displacements, strains, stresses, and equilibrium.

Eshelby Inclusion: Mechanics and Eigenstrains

Explores the Eshelby method for mechanics of inclusions and eigenstrains, focusing on stress and strain fields inside inclusions.

Mechanics of Slender Structures: Elasticity & Buckling

Explores 3D elasticity, beam bending, and buckling phenomena in slender structures.

Mechanics of Transforming Materials

Discusses sources of strain, transformation strains, and behavior of materials undergoing transformation in constrained bodies.

Solid Mechanics Principles: Eigenstrains

Covers eigenstrains, deformations in a body not caused by stress, and their significance in mechanics.

Laminate Analysis: Introduction

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

Laminate Analysis: Introduction

Introduces laminate analysis, covering plane stress, rotation in 2D, and special laminates.

Mechanics of Slender Structures: Final Review and Overview

Covers the main learning objectives of ME-411, focusing on dimensional analysis, scalings, and mechanical elements.

Mechanics: Equilibrium Points and Stability

Explores equilibrium points and stability in mechanical systems, analyzing how systems return to or move away from their positions after disturbances.

3D Linear Elasticity & Beams

Covers 3D linear elasticity, stress, strain, beams' behavior under loads, and torsion.

Introduction to Structural Mechanics: Stress and Strain

Covers stress equilibrium, strain, and constitutive equations in 2D and 3D.

Structural Mechanics: Beam Bending and Boundary Conditions

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

Ellipsoidal Void Stress Concentrations

Explores stress concentrations on ellipsoidal void surfaces and the impact of inclusion on stress distribution.

3D Linear Elasticity & Beams

Introduces 3D linear elasticity, beams, dimensional analysis, and mechanics of slender structures.

Geomechanics: Course Introduction

Introduces the study of geomechanics, covering the behavior of soils, rocks, and concrete in civil engineering applications.

Equilibrium in Mechanics

Delves into equilibrium in mechanics through practical experiments and virtual work principles.

Structural Mechanics Fundamentals

Covers the fundamentals of structural mechanics, including materials, mechanics vocabulary, the Eiffel Tower, and the collapse of the Quebec Bridge.

Eshelby Inclusion Mechanics

Explores the Eshelby method for ellipsoidal inclusions and the mechanics of particles undergoing shape changes due to eigenstrains.

Mechanics of Continuous Media

Explores stress-strain relationships, equilibrium of forces, and material properties in mechanics.

Mechanics of Slender Structures: Elasticity, Plates, Shells

Covers the dimensional reduction in slender structures, constitutive laws, and mechanics of plates and shells.