Book contents
- Frontmatter
- Contents
- Preface
- Acknowledgements
- 1 Introduction
- 2 Some physical techniques for studying polymers
- 3 Molecular sizes and shapes and ordered structures
- 4 Regular chains and crystallinity
- 5 Morphology and motion
- 6 Mechanical properties I – time-independent elasticity
- 7 Mechanical properties II – linear viscoelasticity
- 8 Yield and fracture of polymers
- 9 Electrical and optical properties
- 10 Oriented polymers I – production and characterisation
- 11 Oriented polymers II – models and properties
- 12 Polymer blends, copolymers and liquid-crystal polymers
- Appendix: Cartesian tensors
- Solutions to problems
- Index
9 - Electrical and optical properties
Published online by Cambridge University Press: 05 June 2012
- Frontmatter
- Contents
- Preface
- Acknowledgements
- 1 Introduction
- 2 Some physical techniques for studying polymers
- 3 Molecular sizes and shapes and ordered structures
- 4 Regular chains and crystallinity
- 5 Morphology and motion
- 6 Mechanical properties I – time-independent elasticity
- 7 Mechanical properties II – linear viscoelasticity
- 8 Yield and fracture of polymers
- 9 Electrical and optical properties
- 10 Oriented polymers I – production and characterisation
- 11 Oriented polymers II – models and properties
- 12 Polymer blends, copolymers and liquid-crystal polymers
- Appendix: Cartesian tensors
- Solutions to problems
- Index
Summary
Introduction
As indicated in chapter 1, the first electrical property of polymers to be valued was their high electrical resistance, which made them useful as insulators for electrical cables and as the dielectric media for capacitors. They are, of course, still used extensively for these purposes. It was realised later, however, that, if electrical conduction could be added to the other useful properties of polymers, such as their low densities, flexibility and often high resistance to chemical attack, very useful materials would be produced. Nevertheless, with few exceptions, conducting polymers have not in fact displaced conventional conducting materials, but novel applications have been found for them, including plastic batteries, electroluminescent devices and various kinds of sensors. There is now much emphasis on semiconducting polymers. Figure 9.1 shows the range of conductivities that can be achieved with polymers and compares them with other materials.
Conduction and dielectric properties are not the only electrical properties that polymers can exhibit. Some polymers, in common with certain other types of materials, can exhibit ferroelectric properties, i.e. they can acquire a permanent electric dipole, or photoconductive properties, i.e. exposure to light can cause them to become conductors. Ferroelectric materials also have piezoelectric properties, i.e. there is an interaction between their states of stress or strain and the electric field across them. All of these properties have potential applications but they are not considered further in this book.
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- Chapter
- Information
- An Introduction to Polymer Physics , pp. 248 - 289Publisher: Cambridge University PressPrint publication year: 2002
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