Properties influenced by chemical bonding and crystal structure. Electrical (conductors, semiconductors and insulators), thermal expansion, thermal conductivity, optical, mechanical (strength, ductility, elasticity, hardness and wear), melting points. Definitions, units, typical values and empirical evaluations.

Strength and surface energy. Cracks and stress concentrations. Griffiths crack theory. Toughness in non-metals, the weak interface. Dislocations and ductility. Fatigue and creep. Point defects. Hardening techniques. Diffusion in solids. Survey of material testing techniques: Radiography, Ultrasonic, Eddy currents, hardness (Brinell, Rockwell, Vickers), impact testing, adhesion testing, tensile test.

Lattice types, polymorphism. Alloys: binary alloys of the common metals; Solid solution strengthening, Interstitial vs substitutional. Dispersion strengthening, phase rule; phase diagrams. Interpretation of microstructures for irons and steels, brasses and bronzes and simple alloys of aluminium, lead/tin. Methods employed to increase hardness. Processing and fabrication routes for metals; casting, forming and joining. Classification of steels.

Polymers: Molecular structure, microstructure; crystalline and amorphous polymers. The glass transition temperature. Mechanical behaviour; yielding and fracture. Polymerisation techniques and polymer processing. Chemical properties; degradation, permeability, solubility. Electrical and optical properties. Action of additives; light stabilisers, flame-retardants. Ceramics: Classification, traditional ceramics, glasses, engineering ceramics. Structures of ceramics. Processing and fabrication routes for ceramics and glasses. Structural Ceramics: Alumina, PSZ, Silicon Carbide, Silicon Nitride, Sialons. Functional Ceramics: electroceramics, bioceramics, ceramic magnets. Composite Properties: toughening, fracture, elastic behaviour, Dispersion strengthened, particle reinforced and fibre reinforced composites. Commercial composites; Metal Matrix composites, Polymer Matrix Composites, Ceramic Matrix composites.

The role of materials in mechanical design from the stone age to the synthetic age; economic advantage; materials as liberators; environmental degradation and destruction. The role of materials in today's environment: direct; indirect. Costs: manufacturing; social; other. Use material selection charts to identify the material class appropriate for a particular application. Trends in consumption and manufacturing. Sintering. Coating. Surface modification: ion implantation, vacuum and high pressure plasma modification. Green nanotechnologies for the manufacture and reuse of materials.