Polymers and Composites

Core modules:

Essential Polymer Chemistry

This module introduces essential chemistry of polymers include polymer structure, synthesis of polymers, their characterisation and physicochemical behaviours. Topics include structural features of polymers and how these affect properties, synthesis of polymers via step and chain growth routes, determination of molar mass, and thermal characterisation.

15 credits

Polymer Laboratory

This unit covers the fundamentals of practical polymer construction and analysis. Topics covered include polymer synthesis via a number of methods (including chain- and step-reaction routes). A range of analytical techniques will also be introduced. These will include size-exclusion chromatography, viscosity analysis, and spectroscopy (IR and NMR). Experiments involving the modification and application of polymers will also be studied.

15 credits

The Physics of Polymers

The aim of the module is to introduce the general properties of thermoplastics: their molecular structures, their physical and mechanical properties, and how these properties can be modified by means e.g. of chemistry, additives and processing condition for engineering applications. The module also introduces the fundamentals of amorphous polymer solids and their behaviour under deformation. Topics covered include conformations of polymer chains, rubber elasticity, viscoelasticity, time-temperature superposition, glass-transition, yield, craze etc. After this module you are expected to understand the mechanical properties of typical polymers, as well as their dependence on temperature, time scale, and molecular structures.

15 credits

Composite Materials and Micromechanics

This module starts with an introduction to the different types of composite materials that either exist in nature or are man-made. Reinforcing theories are discussed as are the strengths and weaknesses of composite materials. The aim is to acquaint students with the constituents of composite materials, fibres and matrices. Running parallel to this is an examination of composite materials from a micromechanics point of view. Fibre statistics, classical laminate theory and shear lag theory (and more) are used to predict and understand the properties of composites. A series of problem classes are used to help students practise using the equations and interpreting the output.

 

15 credits

Polymer Materials Science and Engineering

The aim of the module is to demonstrate the relationship between chemical structure, molecular organisation, microstructure and physical properties of polymers in the solid state, to draw parallels between synthetic polymers and biopolymers, to introduce the types of high-strength high-modulus polymers, their processing, properties and application, and to introduce liquid crystals and LC polymers.

15 credits

Design and Manufacture of Composites

This module is designed to provide you with an understanding of both the design and manufacture of polymer composites and is presented in two sections. First, the design of composites is taught via tutorials on classical laminate theory. An extended series of worked examples provides you with the basic tools you need to design effective composite parts. Second, the manufacture of composites is taught via lectures. You will learn multiple routes for making composite parts alongside practical issues such as defects, machining/joints, failure, testing and non destructive testing, repair and SMART composites.

15 credits

Polymer Processing

This module provides you with a detailed description of advanced polymer processing as applied to modern industrial applications. The fundamental concepts behind polymer melt dynamics and solidification will be explored and will provide the theoretical basis for the forming processes. The manufacturing processes themselves will be described giving you the ability to choose between them allowing informed decisions regarding commercial applications. The use of real-world case studies and reverse engineering examples in dedicated problem classes will provide practical experience of decision making in polymer processing.

15 credits

Technologies for Sustainability

Our current manufacturing technologies for chemicals, plastics and construction materials, are carbon intensive technologies and in order to maintain our living standards we need to decarbonise those technologies. In order to achieve this overarching aim, we need to make better use of fossil-based and renewable resources, and move towards a circular economy. Topics include the current status of the industry, life-cycle analysis, non-fossil fuel and feedstocks, and reuse reforming and recycling. This will be focused to the following main areas: Fine chemicals and commodities. This module will discuss the current state-of-the-art of fine chemicals and commodities manufacturing and how to minimize their impact to the environment. Plastic and polymers. Plastic waste is a growing problem and this course will discuss the challenges associated with current plastics, what the alternatives are and whether they will be feasible.

15 credits

Project

Students undertake a project on a topic agreed with their allocated academic supervisor; supervisor allocation takes into accounts students' specific interests. The project is an original research investigation carried out within a research group in the Department; to develop students' abilities to interact within a research group a defined piece of group work is undertaken early in the project. All projects include a literature survey involving students reading original papers and review articles from the scientific and technical literature. Most projects involve extensive laboratory work although some may be based primarily on a survey of the published literature or computational studies. The assessment of the project includes assessment of the group work, an interim report and final report along with a presentation on the work to staff and other students and an oral examination. Conduct throughout the project is also assessed.

60 credits