THE BOOK CORNER - “MULTI-SCALE QUANTUM MODELS FOR BIOCATALYSIS: MODERN TECHNIQUES AND APPLICATIONS"

Multi-scale Quantum Models for Biocatalysis: Modern Techniques and Applications

Series: Challenges and Advances in Computational Chemistry and Physics , Vol. 7
York, Darrin M.; Lee, Tai-Sung (Eds.)
Publisher: Springer
2009, Approx. 600 p., Hardcover
ISBN: 978-1-4020-9955-7


About this book
Multi-scale Quantum Models for Biocatalysis: Modern Techniques and Applications explores various molecular modelling techniques and their applications in providing an understanding of the detailed mechanisms at play during biocatalysis in enzyme and ribozyme systems. These areas are reviewed by an international team of experts in theoretical, computational chemistry, and biophysics.
This book has three sections that group together different aspects of multi-scale quantum simulations. The first section consists of four chapters that describe strategies for multi-scale quantum models and present an overview of the current state-of-the-art molecular modelling methodologies most relevant to handling these complex systems with quantum mechanics and molecular simulation. With five chapters, the second section mainly focuses on the current efforts to improve the accuracy of quantum calculations using simplified empirical model forms. The last section consists of five chapters focused on the applications of important biological systems using multi-scale quantum models. This book presents detailed reviews concerning the development of various techniques, including ab initio molecular dynamics, density functional theory, combined QM/MM methods, solvation models, force field methods, and free-energy estimation techniques, as well as successful applications of multi-scale methods in the biocatalysis systems including several protein enzymes and ribozymes.
Multi-scale Quantum Models for Biocatalysis: Modern Techniques and Applications is an excellent source of information for research professionals involved in computational chemistry and physics, material science, nanotechnology, rational drug design and molecular biology. It is also likely to be of interest to graduate and undergraduate students exposed to these research areas.
Written for:
Researchers and students in computational chemistry and physics, materials science, nanotechnology, rational drug design and molecular biology.
Keywords: Biocatalysis; Free Energy Methods; Linear Scaling Techniques; Path Integrals; Polarizable Force Fields; QM/MM methods; Solvent Boundries ; abinitio MD

For more information please visit: http://www.springer.com/chemistry/book/978-1-4020-9955-7