Graph Theoretical Approaches to Chemical Reactivity
The progress in computer technology during the last 10-15 years has enabled the performance of ever more precise quantum mechanical calculations related to structure and interactions of chemical compounds. However, the qualitative models relating electronic structure to molecular geometry have not p...
| Other Authors: | , |
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| Format: | eBook |
| Language: | English |
| Published: |
Dordrecht
Springer Netherlands
1994, 1994
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| Edition: | 1st ed. 1994 |
| Series: | Understanding Chemical Reactivity
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| Subjects: | |
| Online Access: | |
| Collection: | Springer Book Archives -2004 - Collection details see MPG.ReNa |
Table of Contents:
- 1. Introduction to Graph Theory
- 1. Chemical Graph Theory
- 2. Representation and Characterization of a Graph
- 3. Realization of a Graph
- 4. Operations on Graphs
- 5. References
- 2. The Interplay Between Graph Theory and Molecular Orbital Theory
- 1. Introduction
- 2. Fundamentals of Graph Theory
- 3. Isomorphism of Graph Spectral Theory and Hückel Molecular Orbital Theory
- 4. Hückel Spectrum
- 5. Topological Effect on Molecular Orbitals
- 6. The HOMO-LUMO Separation
- 7. Topological Charge Stabilization
- 8. Localization Energy
- 9. Concluding Remarks
- 10. References
- 3. Topological Control of Molecular Orbital Theory:A Comparison of µ2-Scaled HüCkel Theory and Restricted Hartree-Fock Theory for Boranes and Carboranes
- 1. Introduction
- 2. Calculational Method
- 3. The Method of Moments
- 4. Elemental Boron
- 5. BnHn2-Clusters
- 6. The ?-Parameter of B10H102-
- 7. Reaction Pathways
- 8. Conclusion
- 9. References
- 4. Polyhedral Dynamics
- 1. Introduction
- 2. The Topology of Polyhedra
- 3. Polyhedral Isomerizations
- 4. Microscopic Models: Diamond-Square-Diamond Processes and Gale Diagrams
- 5. Macroscopic Models: Topological Representations
- 6. Literature References
- 5. Reaction Graphs
- 1. Introduction
- 2. Reaction Graphs of Rearrangements Via Carbocations
- 3. Automerization of Bulvalene, Other Valence Isomers of Annulenes,and Azabullvalene
- 4. Rotation in Molecular Propellers
- 5. Reaction Graphs for Rearrangements of Metallic Complexes
- 6. Xenon Hexafluoride
- 7. Heptaphosphide Trianion
- 8. Kinetic Graphs, Synthon Graphs, and Graph Transforms
- 9. Conclusions
- 10. References
- 6. Discrete Representations of Three-Dimensional Molecular Bodies and Their Shape Changes in Chemical Reactions
- 1. Introduction and Review of Basic TopologicalConcepts of Molecular Shape Representation
- 2. Molecular Shape Representation by Nuclear Potential Contours(NUPCO’s)
- 3. Molecular Topology and Topological Invariants
- 4. Applications of Topological Indices to Chemical Reactivity
- 5. Conclusions
- 6. References
- 9. Graph-Theoretical Models of Complex Reaction Mechanisms and Their Elementary Steps
- 1. Introduction
- 2. Graph-Theoretical Approach to Studies in the Elementary Stepsof Complex Reactions
- 3. Classification and Coding of Linear Reaction Mechanisms By UsingKinetic Graphs
- 4. Application of Bipartite Graphs and Stoichiometric Matrices to theDescription of Linear and Nonlinear Reaction Mechanisms
- 5. Topological Aspects of Complex Reaction Mechanisms
- 6. References
- 3. Topological Patterns of NUPCO Sequences
- 4. Shape Changes of NUPCO Sequences Along Reaction Paths and in Conformational Domains
- 5. Shape Changes of NUPCO’s in Conformational Changes and inMolecular Deformations; NUPCO Shape Invariance Domains of the Configuration Space
- 6. Local Shape Invariance of NUPCO’s and the Transfer of FunctionalGroups in Chemical Reactions
- 7. Summary
- 8. References
- 7. The Invariance of Molecular Topology in Chemical Reactions
- 1. Introduction
- 2. From a Lewis Diagram to the Pseudo-Graph and Graphoid
- 3. From Graph (Graphoid) to Surface
- 4. What Is the Topological Homeomorphism from the Chemical Pointof View?
- 5. The Invariance of the Euler Characteristic in Chemical Reactions
- 6. The Main Theorem
- 7. Conclusion
- 8. References and Notes
- 8. Topological Indices and Chemical Reactivity
- 1. Introduction
- 2. Basic Principles Underlying the Topological Nature of Chemical Reactivity