A Practical Introduction to the Simulation of Molecular Systems

Updated edition introducing a wide-range of techniques for the simulation of molecular systems at the atomic level. Employs Python.

Martin J. Field (Author)

9780521852524, Cambridge University Press

Hardback, published 19 July 2007

344 pages, 26 exercises
25.5 x 18 x 2 cm, 0.848 kg

Review of the first edition: 'The book should be particularly useful to all active practitioners in molecular simulation techniques, chiefly graduate students and researchers in universities and industry … this book is a valuable addition to my shelf and one that I must make sure doesn't disappear because my research group has taken off with it!' Neil L. Allan, Chemistry and Industry

Molecular simulation is a powerful tool in materials science, physics, chemistry and biomolecular fields. This updated edition provides a pragmatic introduction to a wide range of techniques for the simulation of molecular systems at the atomic level. The first part concentrates on methods for calculating the potential energy of a molecular system, with new chapters on quantum chemical, molecular mechanical and hybrid potential techniques. The second part describes methods examining conformational, dynamical and thermodynamical properties of systems, covering techniques including geometry-optimization, normal-mode analysis, molecular dynamics, and Monte Carlo simulation. Using Python, the second edition includes numerous examples and program modules for each simulation technique, allowing the reader to perform the calculations and appreciate the inherent difficulties involved in each. This is a valuable resource for researchers and graduate students wanting to know how to use atomic-scale molecular simulations. Supplementary material, including the program library and technical information, available through www.cambridge.org/9780521852524.

Preface to the second edition
Preface to the first edition
1. Preliminaries
2. Chemical models and representations
3. Coordinates and co-ordinate manipulations
4. Quantum chemical models
5. Molecular mechanics
6. Hybrid potentials
7. Finding stationary points and reaction paths
8. Normal mode analysis
9. Molecular dynamics simulations I
10. More on non-bonding interactions
11. Molecular dynamics simulations II
12. Monte Carlo simulations
Appendix 1 - The pDynamo library
Appendix 2 - Mathematical appendix
Appendix 3 - Solvent boxes and solvated molecules
Bibliography.

Subject Areas: Materials science [TGM], Mechanical engineering & materials [TG], Physical chemistry [PNR]