Condensed Matter Physics
A Very Short Introduction
Price: 350.00 INR
We sell our titles through other companies
Disclaimer :You will be redirected to a third party website.The sole responsibility of supplies, condition of the product, availability of stock, date of delivery, mode of payment will be as promised by the said third party only. Prices and specifications may vary from the OUP India site.
ISBN:
9780198845423
Publication date:
10/12/2025
Paperback
176 pages
174x111mm
Price: 350.00 INR
We sell our titles through other companies
Disclaimer :You will be redirected to a third party website.The sole responsibility of supplies, condition of the product, availability of stock, date of delivery, mode of payment will be as promised by the said third party only. Prices and specifications may vary from the OUP India site.
ISBN:
9780198845423
Publication date:
10/12/2025
Paperback
176 pages
Part of Very Short Introductions
Ross H. McKenzie
- Provides a modern introduction to a major field of physics that underpins silicon chips and liquid crystals, and explores deep questions about the nature and behaviour of matter
- Focuses on introducing the fundamental concepts of condensed matter physics and uses concrete examples to illustrate these
- Highlights the role of emergence (the whole is greater than the sum of the parts) in condensed matter physics
- Shows how condensed matter physics links to other fields of physics and to other sciences
- Part of the bestselling Very Short Introductions series
Rights: OUP UK (INDIAN TERRITORY)
Ross H. McKenzie
Description
There are many more states of matter than just solid, liquid, and gas. Examples include liquid crystal, magnet, glass, and superconductor. New states are continually, and unexpectedly, being discovered. Some states, such as superconductor, can act like Schrödinger's cat and exhibit the weirdness normally associated with the quantum theory of atoms, photons, and electrons. Condensed matter physics seeks to understand how states of matter and their distinct physical properties emerge from the atoms of which a material is composed.
A system of many interacting parts can have properties that the parts do not have. Water is wet, but a single water molecule is not. Your brain is conscious, but a single neuron is not. Such emergent phenomena are central to condensed matter physics and also occur in many fields, from biology to computer science to sociology, leading to rich intellectual connections. When do quantitative differences become qualitative differences? Can simple models describe rich and complex behaviour? What is the relationship between the particular and the universal? How is the abstract related to the concrete? Condensed matter physics is all about these big questions.
The materials in silicon chips, liquid crystal displays, and magnetic computer memories, may have transformed society, but understanding them has transformed how we think about complex systems.
About the author
Ross H. McKenzie is an Emeritus Professor of Physics at the University of Queensland, Brisbane, Australia. His research in condensed matter physics focuses on using quantum theory to understand complex materials, ranging from organic superconductors to fluorescent proteins. He has given lectures to schools and to the public on this topic, as well as running a blog, Condensed Concepts, which was featured in an issue of Physics World.
Ross H. McKenzie
Table of contents
Preface
Acknowledgements
List of illustrations
1:What is condensed matter physics?
2:A multitude of states of matter
3:Symmetry matters
4:The order of things
5:Adventures in flatland
6:The critical point
7:Quantum matter
8:Topology matters
9:Emergence
10:The endless frontier
References
Further reading
Appendix: List of Nobel Prizes in Condensed Matter Physics
Index
Ross H. McKenzie
Description
There are many more states of matter than just solid, liquid, and gas. Examples include liquid crystal, magnet, glass, and superconductor. New states are continually, and unexpectedly, being discovered. Some states, such as superconductor, can act like Schrödinger's cat and exhibit the weirdness normally associated with the quantum theory of atoms, photons, and electrons. Condensed matter physics seeks to understand how states of matter and their distinct physical properties emerge from the atoms of which a material is composed.
A system of many interacting parts can have properties that the parts do not have. Water is wet, but a single water molecule is not. Your brain is conscious, but a single neuron is not. Such emergent phenomena are central to condensed matter physics and also occur in many fields, from biology to computer science to sociology, leading to rich intellectual connections. When do quantitative differences become qualitative differences? Can simple models describe rich and complex behaviour? What is the relationship between the particular and the universal? How is the abstract related to the concrete? Condensed matter physics is all about these big questions.
The materials in silicon chips, liquid crystal displays, and magnetic computer memories, may have transformed society, but understanding them has transformed how we think about complex systems.
About the author
Ross H. McKenzie is an Emeritus Professor of Physics at the University of Queensland, Brisbane, Australia. His research in condensed matter physics focuses on using quantum theory to understand complex materials, ranging from organic superconductors to fluorescent proteins. He has given lectures to schools and to the public on this topic, as well as running a blog, Condensed Concepts, which was featured in an issue of Physics World.
Table of contents
Preface
Acknowledgements
List of illustrations
1:What is condensed matter physics?
2:A multitude of states of matter
3:Symmetry matters
4:The order of things
5:Adventures in flatland
6:The critical point
7:Quantum matter
8:Topology matters
9:Emergence
10:The endless frontier
References
Further reading
Appendix: List of Nobel Prizes in Condensed Matter Physics
Index
Jim Baggott
Frank Close
John C. H. Spence
Statistical Mechanics: Entropy, Order Parameters, and Complexity
James P. Sethna
Quantum Optomechanics and Nanomechanics
Pierre-François Cohadon, Jack Harris, Florian Marquardt, Leticia Cugliandolo
Frank Close
David Blockley
Christopher Hall
A Concise Guide to Communication in Science and Engineering
David H. Foster
Frank Close
