Faculty : Faculty of Engineering and Applied Sciences

School : Materials Science and Engineering

Course Description :

Give the student the knowledge about the advances of materials science and technology – Advanced materials for engineers – Production /structure /property/function relation and application – Advanced materials for various fields of applications –Metallic/ceramic/polymeric materials/thin films/nanomaterials (production, processing, applications and their characterizations).

Faculty : Faculty of Engineering and Applied Sciences

School : Materials Science and Engineering

Course Description :

Fundamentals of stress and strain analysis- State of stress – Principle stresses – Theory of elasticity-Theory of plasticity – Yielding criteria – Tresca yield criteria –Von Mises yield criteria – Plastic deformation mechanisms of single crystals and polycrystalline-Strain hardening theories in single crystal and polycrystalline – Mechanical behavior under normal and shear stress – High temperature and high strain rate deformations – Materials behavior under creep conditions – Cyclic materials deformation behavior – Formability in hot working – Ductile and brittle Fracture of materials (Mechanics and mechanisms)

Faculty : Faculty of Engineering and Applied Sciences

School : Materials Science and Engineering

Course Description :

Introduction to mathematical techniques necessary for materials science and engineering– Calculations of empirical and semi-empirical materials models, material models for metals – materials models for elastomers – material models for composites – materials models for ceramics and porous materials – relation between microscopic and macroscopic material models- Eigen value problems involving material – Equilibrium problems involving materials- transient problems involving materials – Engineering based numerical solution techniques- Multi-physics analysis- statistical solution techniques – Theory molecular dynamics simulation – Theory of finite element analysis.

Faculty : Faculty of Engineering and Applied Sciences

School : Materials Science and Engineering

Course Description :

Definition & scope of ceramics and ceramic materials – Classification of ceramic materials – Conventional and advanced areas of applications – Bonding in Ceramics – Structures of Ceramics – Structure of Covalent Ceramics – Structure of Silicates – Lattice Parameters and Density – Ceramic Fabrication Processes – Gas-Phase Reactions – Chemical/Physical Vapor Deposition – Directed Metal Oxidation – Reaction Bonding, Liquid Precursor Methods, Sol–Gel Processing, Polymer Pyrolysis – Fabrication from Powders – Powder Consolidation and Forming of Ceramics – Diffusion and Electrical Conductivity – Diffusion – Electrical Conductivity – Ambipolar Diffusion – Defect Diffusion Coefficients – Phase Equilibria of some ceramics systems – Binary Systems, Ternary Systems – Mechanical Properties: Fracturing: Brittleness – Fracture Toughness – Strength of Ceramics – Toughening Mechanisms.

Faculty : Faculty of Engineering and Applied Sciences

School : Materials Science and Engineering

Course Description :

Chemical structures –Polymerization, molar masses – Chain conformations. Rubber elasticity– Polymer solutions – Glass state and aging Mechanical properties – Fracture mechanics and viscoelasticity – Dielectric properties – Polymer liquid crystals – Semi-crystalline polymers-Polymer melts – Rheology and processing-Thermal analysis- Microscopy – Diffractometry and spectroscopy of polymers. Computer simulations of polymer-based.