Aims

The aims of the course are to:

• show how the fundamental principles of thermodynamics and diffusion govern the properties and microstructure evolution of materials (Lectures 1-8);
• employ these principles to extend understanding of materials processing techniques (heat treatment, casting, forging), and how they can be used to manipulate microstructure and properties for particular engineering applications (Lectures 9-16).

Objectives

As specific objectives, by the end of the course students should be able to:

• By the end of Lectures 1-8:
• Apply thermodynamic and kinetic principles to predict a range of material behaviour, including rubber elasticity, oxidation and corrosion.
• Describe the concept of the thermodynamic driving force for microstructural change, explain the principles of phase transformations, and derive models for phase nucleation.
• Apply the thermodynamic principles of phase equilibrium in order to interpret phase diagrams.
• Understand how diffusion occurs, and derive and apply mathematical models of one-dimensional diffusion.
• By the end of the Lectures 9-16:
• Explain the importance of composition, thermal history and deformation history in controlling the evolution of microstructure and properties during materials processing.
• Select an appropriate heat treatment schedule for particular metal alloys, in order to deliver the properties required for specific engineering applications.
• Understand the analogy between mass diffusion and thermal diffusion, and use this to derive and apply mathematical models for heat flow in materials processing.
• Describe and compare the attributes of alternative shaping processes (e.g. casting, forging), and the consequences for alloy selection and properties.
• Derive and apply mathematical models describing the deformation response of materials, including metal forming processes and temperature-dependent creep.

Content

Materials thermodynamics and diffusion (8L, Dr Alexandre Kabla)

(1) Chap. 17, GLU2; (2) Chap. 21,24-27; (3) Chap. 3-7; (4) Chap. 5,9,17 (5) Chap. 6, (6) Chap. 7, sections 7.4 and 7.5 

• Role of entropy: entropic interpretation of the ideal gas law; polymer elasticity.
• Phases and phase diagrams (teach yourself).
• Free energy: thermodynamic basis of phase equilibrium; osmosis.
• Phase transformations: thermodynamic and kinetic principles; theory of nucleation and growth. 
• Theory of diffusion in solids.
• Oxidation and corrosion.

Materials processing (8L, Dr Graham McShane)

(1) Chap. 6, 13, 18, 19, GLU2;  (2) Chap. 20,22,23;  (3) Chap. 8-13,15,16,21,24-26,28; (4) Chap. 7,8,10,11,15.

• Heat treatment of aluminium alloys and steels: TTT and CCT diagrams; practical heat treatment; analysis of heat flow; surface engineering (case hardening).
• Shaping processes for metals:  casting; deformation processing (rolling, forging); annealing, recovery and recystallisation; grain size control; modelling of deformation processing.
• Polymer processing: crystallisation; injection moulding; fibre drawing.
• Processing materials to operatre at high temperatures:  high temperature deformation and creep in metals; deformation mechanism maps; achieving creep resistance.

REFERENCES

(1) ASHBY, M., SHERCLIFF, H. & CEBON, D. MATERIALS: ENGINEERING, SCIENCE, PROCESSING AND DESIGN
(2) ASHBY, M.F. & JONES, D.R.H. ENGINEERING MATERIALS 1
(3) ASHBY, M.F. & JONES, D.R.H. ENGINEERING MATERIALS 2
(4) CALLISTER, W.D. MATERIALS SCIENCE AND ENGINEERING: AN INTRODUCTION
(5) JONES, R.A.L. SOFT CONDENSED MATTER
(6) TABOR, D. GASES, LIQUIDS AND SOLIDS
 

This syllabus contributes to the following areas of the UK-SPEC standard:

Toggle display of UK-SPEC areas.

 
Last modified: 11/09/2020 20:11