This book describes how chemical reactions take place at the atomic level and how one can calculate the rate of such reactions. The book features a systematic and comprehensive presentation of the subject with a wide range of examples and end-of-chapter problems.
This book describes how chemical reactions take place at the atomic level and how one can calculate the rate of such reactions. The book features a systematic and comprehensive presentation of the subject with a wide range of examples and end-of-chapter problems.
Niels Engholm Henriksen holds a Ph.D. in chemical physics from the Technical University of Denmark and a D.Sc. from the University of Copenhagen. After his postdoctoral work in the United States with E.J. Heller, he became a senior research scholar at the University of Copenhagen. Since 1991, NEH has been affiliated with the Technical University of Denmark. His research interests cover various aspects of theoretical molecular reaction dynamics including femtochemistry. Flemming Yssing Hansen has a Ph.D. in physical chemistry from the Technical University of Denmark. From 1973-2012 he held a position as associate professor in physical chemistry at the Technical University of Denmark and served during that time a 15 year period as chairman of the Department of Physical Chemistry. Since 2012, he has held an emeritus position at the Department of Chemistry, the Technical University of Denmark. He has spent extensive time in Chile and USA as a visiting professor at various universities and was appointed as adjunct professor in Physics at the University of Missouri-Columbia. His research interests cover a wide range of aspects within thermodynamics, statistical mechanics, quantum mechanics and molecular dynamics simulations.
Inhaltsangabe
1: Introduction PART I: Gas-phase dynamics 2: From microscopic to macroscopic descriptions 3: Potential energy surfaces 4: Bimolecular reactions, dynamics of collisions 5: Rate constants, reactive flux 6: Bimolecular reactions, transition-state theory 7: Unimolecular reactions 8: Microscopic interpretation of Arrhenius parameters PART II: Condensed-phase dynamics 9: Introduction to condensed-phase dynamics 10: Static solvent effects, transition-state theory 11: Dynamic solvent effects, Kramers theory and beyond PART III: Appendices Appendix A: Adiabatic and non-adiabatic electron-nuclear dynamics Appendix B: Statistical mechanics Appendix C: Microscopic reversibility and detailed balance appendix D: Cross-sections in various frames appendix E: Internal kinetic energy, Jacobi coordinates Appendix F: Small-amplitude vibrations, normal-mode coordinates Appendix G: Quantum mechanics Appendix H: An Integral Appendix I: Dynamics of random processes Appendix J: Multidimensional integrals, Monte Carlo method
