Many-Body Methods in Chemistry and Physics MBPT and Coupled-Cluster Theory [Hardcover]

This book describes the mathematical and diagrammatic techniques employed in the popular many-body methods to determine molecular structure, properties and interactions.Molecular and atomic interactions are explored using many-body quantum mechanical theory. This book is the first unified treatment describing the popular many-body-perturbation theory (MBPT) and coupled-cluster (CC) quantum mechanical theory. It introduces an unambiguous approach, teaching the reader to understand and confidently derive relevant equations for current methods.Molecular and atomic interactions are explored using many-body quantum mechanical theory. This book is the first unified treatment describing the popular many-body-perturbation theory (MBPT) and coupled-cluster (CC) quantum mechanical theory. It introduces an unambiguous approach, teaching the reader to understand and confidently derive relevant equations for current methods.Written by two leading experts in the field, this book explores the 'many-body' methods that have become the dominant approach in determining molecular structure, properties and interactions. With a tight focus on the highly popular Many-Body Perturbation Theory (MBPT) and Coupled-Cluster theories (CC), the authors present a simple, clear, unified approach to describe the mathematical tools and diagrammatic techniques employed. Using this book the reader will be able to understand, derive and confidently implement relevant algebraic equations for current and even new multi-reference CC methods. Hundreds of diagrams throughout the book enhance reader understanding through visualization of computational procedures and extensive referencing allows further exploration of this evolving area. With an extensive bibliography and detailed index, this book will be suitable for graduates and researchers within quantum chemistry, chemical physics and atomic, molecular and solid-state physics.1. Introduction; 2. Formal perturbation theory; 3. Second quantization; 4. Diagrló0