Lecture 1 - Introduction to Plasticity
Lecture 2 - Stress-Strain Relations
Lecture 3 - Pressure Independent Materials Failure Criteria
Lecture 4 - Pressure Dependent Materials Failure Criteria
Lecture 5 - Components of Plasticity, Kuhn-Tucker conditions
Lecture 6 - Perfectly Plastic Materials and Flow Rule
Lecture 7 - Stress-Strain Relations for Hardening Materials
Lecture 8 - Implementation in Metals
Lecture 9 - Elasto-Plastic Analysis for Composite Materials
Lecture 10 - Linear Elastic Brittle Fracture Models
Lecture 11 - Implementation of Concrete Constitutive Models
Lecture 12 - Elastic Perfectly Plastic Fracture Models for Concrete
Lecture 13 - Plasticity Models: Plain Concrete and FRC
Lecture 14 - Constitutive Models for Confined Concrete
Lecture 15 - Material Damage and Continuum Damage Mechanics
Lecture 16 - Mechanical Representation of Damage and Damage Variables
Lecture 17 - Thermodynamics of damaged material
Lecture 18 - Inelastic Constitutive Equation for Materials with Isotropic Damage
Lecture 19 - Strain Energy Release and Stress Criteria in Damage Development
Lecture 20 - Constitutive and Evolution Equations of Elastic-Plastic Damage
Lecture 21 - Anisotropic Damage Theory and Dissipation Potential Functions
Lecture 22 - Viscoelasticity, Viscoplasticity and Energy-Based Inelastic Damage Theory - Part 1
Lecture 23 - Viscoelasticity, Viscoplasticity and Energy-Based Inelastic Damage Theory - Part 2
Lecture 24 - Strain Gradient Theories
Lecture 25 - Basics of Blast and Impact
Lecture 26 - Overview of Constitutive Material Models for Concrete
Lecture 27 - Concrete Constitutive Models and Their Extension to UHPC
Lecture 28 - Constitutive modeling of concrete under dynamic loading
Lecture 29 - Foundations of One-Dimensional Rate-Independent Plasticity
Lecture 30 - Incremental Elastoplasticity and Convex Return-Mapping Algorithms
Lecture 31 - Finite Element Formulation of Elastoplasticity
