# Computational Physics

Cambridge University Press

Edition: 2, 10/10/2013

EAN 9781107677135, ISBN10: 1107677130

Paperback, 638 pages, 24.4 x 17 x 3.7 cm

Language: English

First published in 2007, this second edition describes the computational methods used in theoretical physics. New sections were added to cover finite element methods and lattice Boltzmann simulation, density functional theory, quantum molecular dynamics, Monte Carlo simulation, and diagonalisation of one-dimensional quantum systems. It covers many different areas of physics research and different computational methodologies, including computational methods such as Monte Carlo and molecular dynamics, various electronic structure methodologies, methods for solving partial differential equations, and lattice gauge theory. Throughout the book the relations between the methods used in different fields of physics are emphasised. Several new programs are described and can be downloaded from www.cambridge.org/9781107677135. The book requires a background in elementary programming, numerical analysis, and field theory, as well as undergraduate knowledge of condensed matter theory and statistical physics. It will be of interest to graduate students and researchers in theoretical, computational and experimental physics.

1. Introduction

2. Quantum scattering with a spherically symmetric potential

3. The variational method for the SchrÃƒÂ¶dinger equation

4. The HartreeÃ¢â‚¬â€œFock method

5. Density functional theory

6. Solving the SchrÃƒÂ¶dinger equation in periodic solids

7. Classical equilibrium statistical mechanics

8. Molecular dynamics simulations

9. Quantum molecular dynamics

10. The Monte Carlo method

11. Transfer matrix and diagonalisation of spin chains

12. Quantum Monte Carlo methods

13. The infinite element method for partial differential equations

14. The lattice Boltzmann method for fluid dynamics

15. Computational methods for lattice field theories

16. High performance computing and parallelism

Appendix A. Numerical methods

Appendix B. Random number generators

References

Index.

'The growing importance of computational physics to physics research as a whole will depend not only on increasingly powerful computers, but also on the continuing development of algorithms and numerical techniques for putting these machines to use. Furthermore, physics departments will need to augment their curricula to provide students with the skills needed to perform research using computers ... In Computational Physics, [Jos] Thijssen has produced a book that is well suited to meeting these needs ... This book makes it easier to approach a new topic and encourages the reader to consider a modular approach when writing programs.' Physics Today