Vibronic coupling density : understanding molecular deformation
著者
書誌事項
Vibronic coupling density : understanding molecular deformation
(Springer briefs in molecular science / series editor, Seth C. Rasmussen)
Springer, c2021
- タイトル別名
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Vibronic coupling density
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注記
Includes bibliographical references
内容説明・目次
内容説明
This book introduces vibronic coupling density and vibronic coupling constant analyses as a way to understand molecular structure and chemical reactions. After quantum study, the behavior of electrons circulating around nuclei led to the principal concept that underlies all explanations in chemistry. Many textbooks have given plausible explanations to clarify molecular structure-for example, the bond elongation of ethylene under anionization and the nonplanar structure of ammonia. Frontier molecular orbital concepts were proposed to visualize the path of chemical reactions, and conventional explanations gave students a familiarity with molecular structures in terms of the electronic state. By contrast, this book offers a more rational and more convincing path to understanding. It starts from the ab initio molecular Hamiltonian and provides systematic, rational approaches to comprehend chemical phenomena. In this way, the book leads the reader to a grasp of the quantitative evaluation of the force applied under the molecular deformation process. As well, guidelines are offered for integrating the traditional "hand-waving" approach of chemistry with more rational and general VCD and VCC alternatives along with the outlook for newly functionalized chemical systems.
目次
1. Introduction: What is understanding chemistry?.- 2. How the chemical processes are qualitatively explained by the simple molecular orbital theory.- 3. How the chemical processes are visualized and quantified by VCD and VCC.- 4. Relationship between Fukui function and VCD.- 5. Transition dipole moment density.- 6. Outlooks for new chemical systems by VCD and VCC.- 7. Appendix.
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