Interatomic Forces in Condensed Matter (Oxford Series on Materials Modelling) [Hardcover]

Mike Finnis (Author)

Book Description

ISBN-10: 0198509774 | ISBN-13: 978-0198509776 | Publication Date: January 1, 2004

There is a continuing growth of interest in the computer simulation of materials at the atomic scale, using a variety of academic and commercial computer programs. In all such programs there is some physical model of the inter-atomic forces, which may be based on something as simple as a pair interaction, such as the Lennard-Jones model, or as complex as a self-consistent, all-electron solution of the quantum mechanical problem. For a student or researcher, the basis of such models is often shrouded in mystery. It is usually unclear how well founded they are, since it is hard to find a discussion of the physical assumptions that have been made in their construction. The lack of clear understanding of the scope and limitations of a given model may lead to its innocent misuse, resulting either in unfair criticism of the model or in the dissemination of nonsensical results.

In the present book, models of inter-atomic forces are derived from a common physical basis, namely the density functional theory. The interested reader will be able to follow the detailed derivation of pairwise potentials in simple metals, tight-binding models from the simplest to the most sophisticated (self-consistent) kind, and various ionic models. The book is self-contained, requiring no more background than provided by an undergraduate quantum mechanics course. It aims to furnish the reader with a critical appreciation of the broad range of models in current use, and to provide the tools for understanding other variants that are described in the literature. Some of the material is new, and some pointers are given to possible future avenues of model development.

Editorial Reviews

Review

`Mike Finnis is an exceptional writer. Not only has he made seminal contributions to the development of interatomic forces, but he is a master at explaining involved and difficult concepts in a transparent and physically intuitive way... This will be the definitive treatment on interatomic forces for years to come.' Adrian P. Sutton FRS, University of Oxford

`I am very excited by the prospect of this book. It promises to be an important resource for a broad readership.' Robert E. Rudd, Lawrence Livermore National Laboratory

About the Author

Mike Finnis is a Fellow of the Institute of Physics and a Member of the Editorial Board of Reports on Progress in Physics.

Product Details

• Hardcover: 304 pages
• Publisher: Oxford University Press, USA (January 1, 2004)
• Language: English
• ISBN-10: 0198509774
• ISBN-13: 978-0198509776
• Product Dimensions: 9.4 x 6.7 x 0.9 inches
• Shipping Weight: 1.6 pounds (View shipping rates and policies)
• Average Customer Review: 4.0 out of 5 stars  See all reviews (1 customer review)
• Amazon Best Sellers Rank: #2,893,197 in Books (See Top 100 in Books)

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Most Helpful Customer Reviews

6 of 6 people found the following review helpful:

4.0 out of 5 stars Great content but could be written in a simpler manner, June 21, 2004

By 

Newton Ooi (Phoenix, Arizona United States) - See all my reviews
(REAL NAME)   

This review is from: Interatomic Forces in Condensed Matter (Oxford Series on Materials Modelling) (Hardcover)

I read this book as preparation for my Ph.D. comprehensive exams. Specifically, I wanted to improve my understanding of materials modelling and density functional theory. This book did accomplish this. It provides a very comprehensive study of how interatomic forces are calculated in solids. Density functional theory, tight binding, empirical potentials, linear response theory, phonon calculation, and elastic constants were all here.

The focus was tight; with minimal straying into related topics such as electronic structure, Monte Carlo, or modelling of gases or liquids. As such, this book is great for materials engineers and scientists, but is useless for chemists and probably most physicists.

The book leans towards the theoretical side; minimal discussion of how the different equations would be implemented into code. Hence don't use this book as a guide to writing a simulation software. But do use it as a guide to understanding how to use a simulation software to obtain results. Suprisingly, the text does not require a lot of prior knowledge in thermodynamics, crystallography, quantum, or solid state; thereby making it more readable for people from a wide range of technical backgrounds.

I recommend this as a textbook for a course on atomistic scale modeling of solids, with one reservation. It is short, well organized, and since it is written by one author, the text flows much better than many other textbooks in materials modelling which are usually written by a team of authors. But it is not written in the simplest manner possible. Many of the concepts are explained in purely mathematical terms; i.e. derivations and proofs. This is great for the mathematically inclined but death to everyone else. Instead, many of the concepts should have been accompanied by figures and diagrams to help the reader visualize what is going on. This is especially true in the chapter on elastic constants. The text delved right into matrix math, when it should have used figures showing how crystal cells of different lattice types can be deformed along different crystallographic directions.