N. D. Epiotis
Theory of Organic Reactions (eBook, PDF)
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N. D. Epiotis
Theory of Organic Reactions (eBook, PDF)
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Produktdetails
- Verlag: Springer Berlin Heidelberg
- Seitenzahl: 290
- Erscheinungstermin: 6. Dezember 2012
- Englisch
- ISBN-13: 9783642668272
- Artikelnr.: 53206197
Dieser Download kann aus rechtlichen Gründen nur mit Rechnungsadresse in A, B, BG, CY, CZ, D, DK, EW, E, FIN, F, GR, HR, H, IRL, I, LT, L, LR, M, NL, PL, P, R, S, SLO, SK ausgeliefert werden.
1. One-Determinental Theory of Chemical Reactivity.- 1.1 General Principles and Computational Schemes.- 1.2 Qualitative One-Determinental Models of Chemical Reactivity.- 1.3 The Static One Electron Molecular Orbital Model.- 1.4 Orbital Energies. The Donor-Acceptor Classification of Molecules and the Concept of Reaction Polarity.- 1.5 One Electron Interaction Matrix Elements and Overlap Integrals.- 1.6 The Woodward-Hoffmann Molecular Orbital Correlation Diagram.- 2. Configuration Interaction Overview of Chemical Reactivity.- 2.1 General Principles.- 2.2 Qualitative Configuration Interaction Models of Chemical Reactivity.- 2.3 The Static Linear Combination of Fragment Configurations Method.- 2.4 The Static Delocalized Configuration Interaction Method.- 2.5 The Dynamic Delocalized Configuration Interaction Method.- 3. The Dynamic Linear Combination of Fragment Configurations Method.- 3.1 Definitions.- 3.2 General Theoretical Considerations.- 3.3 The Interaction of Diabatic Surfaces.- 3.4 Polarity Control of Barrier Heights and Decay Efficiencies.- 3.5 The Effect of Excitation Energy on Photochemical Barrier Height.- 3.6 Diabatic Surface Interrelationships. A Classification of Chemical Reactions.- 4. Even-Even Intermodular Multicentric Reactions.- 4.1 Potential Energy Surfaces for 2?+2? Cycloadditions.- 4.2 The Effect of Polarity. Potential Energy Surfaces for Nonionic and Ionic In 2?+2? Cycloadditions.- 4.3 Pericyclic, Effectively Pericyclic and Quasipericyclic Reactions.- 4.4 The Effect of Unsymmetrical Substitution and the Effect of Conjugative Substitution.- 4.5 The Regiochemistry of 2?+2? Cycloadditions.- 4.6 Isomeric Reactions and the Topochemistry of 2?+2? Cycloreversions.- 4.7 The Topochemistry of Intramolecular Cycloadditions.- 4.8 The Selectivity-PolarityRelationship.- 4.9 Reaction Intermediates and Types of Organic Mechanisms.- 4.10 2?+2? Nonionic Photocycloadditions Involving n?* Excitation.- 4.11 The Effect of Low Lying Diexcited Diabatic Surfaces in Photoreactions.- 4.12 The Problem of Energy Wastage. The Concept of Dual Channel Photoreactions.- 4.13 Generalizations.- 5. The Problem of Correlation Imposed Barriers.- 6. Reactivity Trends of Thermal Cycloadditions.- 6.1 Introduction.- 6.2 Mechanisms of Stereochemical Nonretention in Cycloadditions.- 6.3 Reactivity Trends of Thermal Nonionic 2?+2? Cycloadditions.- 6.4 Reactivity Trends of Thermal Ionic 2?+2? Cycloadditions.- 6.5 The 2?+2? Ionic Cycloaddition Problem.- 6.6 Reactivity Trends of Thermal Nonionic 4?+2? Cycloadditions.- 6.7 Reactivity Trends of Thermal Ionic 4?+2? Cycloadditions.- 7. Reactivity Trends of Singlet Photochemical Cycloadditions.- 7.1 Introduction.- 7.2 The Chorochemistry of Singlet 2?+2? Photocycloadditions.- 7.3 "Unusual" Head to Head vs. Head to Tail Regioselectivity of Photocycloadditions.- 7.4 n?* State Dual Channel Mechanisms of Polar Nonionic Carbonyl Photocycloadditions.- 7.5 ??* State Dual Channel Mechanisms of Polar Nonionic Photocycloadditions.- 8. Miscellaneous Intermolecular Multicentric Reactions.- 8.1 Cycloadditions of Cumulene Systems.- 8.2 The Ene Reaction.- 8.3 1,3 Dipolar Cycloadditions.- 9. ?? A ddition Reactions.- 9.1 Introduction.- 9.2 Potential Energy Surfaces for 2?+2? Additions.- 9.3 Reactivity Trends of 2?+2? Additions.- 10. Even-Odd Multicentric Intermolecular Reactions.- 10.1 Potential Energy Surfaces for 2?+1? Cycloadditions.- 10.2 Reactivity Trends of Cationic Even-Odd Retro-Cycloadditions and Eliminations.- 11. Potential Energy Surfaces for Odd-Odd Multicentric IntermolecularReactions.- 12. Even-Even Intermolecular Bicentric Reactions.- 12.1 Potential Energy Surfaces for Electrophilic and Nucleophilic Additions.- 12.2 Reactivity Trends of Electrophilic and Nucleophilic Substitutions.- 13. Even-Odd Intermolecular Bicentric Reactions.- 13.1 Potential Energy Surfaces for Radical Additions.- 13.2 Reactivity Trends of Radical Substitution Reactions.- 14. Odd-Odd Intermolecular Bicentric Reactions. Potential Energy Surfaces for Geometric Isomerization and Radical Combination.- 15. Odd-Odd Intramolecular Multicentric Reactions.- 15.1 Potential Energy Surfaces for Sigmatropic Shifts.- 15.2 Reactivity Trends of Sigmatropic Shifts.- 16. Even-Even Intramolecular Multicentric Reactions.- 16.1 Potential Energy Surfaces for Ionic Rearrangements.- 16.2 Reactivity Trends of Ionic Rearrangements.- 17. Mechanisms of Electrocyclic Reactions.- 17.1 Introduction.- 17.2 Reactivity Trends of Electrocyclic Reactions.- 18. Triplet Reactivity.- 18.1 Introduction.- 18.2 Excited State Spin Multiplicity and Photochemical Barrier Heights.- 18.3 The Mechanism of Spin Inversion in Triplet Nonionic Photoaromatic Reactions.- 18.4 The Mechanism of Spin Inversion in Triplet Nonionic Photoantiaromatic Reactions.- 18.5 Spin-Orbit Coupling Borrowing.- 18.6 Mechanisms of Triplet Photoreactions.- 18.7 A Model of Triplet Reactivity.- 18.8 Spin-Orbit Coupling and the Chorochemistry of Triplet Photocycloadditions.- 18.9 Spin-Orbit Coupling and the Regiochemistry of Triplet Photoaromatic Substitutions.- 19. Photophysical Processes.- 20. The Importance of Low Lying Nonvalence Orbitals.- 21. Divertissements.- 21.1 Thermal Antiaromatic Pericyclic Reactions.- 21.2 Induced Thermal Pericyclic Reactions.- 21.3 Half-Aromatic Reaction Paths.- 21.4 Ambident Reactivity.- 21.5 The Stereoselectivity of Photocycloadditions: In Search of Antiaromatic Intermediates.- 22. A Contrast of "Accepted" Concepts of Organic Reactivity and the Present Work.- Epilogue.- References.- Author Index.
1. One-Determinental Theory of Chemical Reactivity.- 1.1 General Principles and Computational Schemes.- 1.2 Qualitative One-Determinental Models of Chemical Reactivity.- 1.3 The Static One Electron Molecular Orbital Model.- 1.4 Orbital Energies. The Donor-Acceptor Classification of Molecules and the Concept of Reaction Polarity.- 1.5 One Electron Interaction Matrix Elements and Overlap Integrals.- 1.6 The Woodward-Hoffmann Molecular Orbital Correlation Diagram.- 2. Configuration Interaction Overview of Chemical Reactivity.- 2.1 General Principles.- 2.2 Qualitative Configuration Interaction Models of Chemical Reactivity.- 2.3 The Static Linear Combination of Fragment Configurations Method.- 2.4 The Static Delocalized Configuration Interaction Method.- 2.5 The Dynamic Delocalized Configuration Interaction Method.- 3. The Dynamic Linear Combination of Fragment Configurations Method.- 3.1 Definitions.- 3.2 General Theoretical Considerations.- 3.3 The Interaction of Diabatic Surfaces.- 3.4 Polarity Control of Barrier Heights and Decay Efficiencies.- 3.5 The Effect of Excitation Energy on Photochemical Barrier Height.- 3.6 Diabatic Surface Interrelationships. A Classification of Chemical Reactions.- 4. Even-Even Intermodular Multicentric Reactions.- 4.1 Potential Energy Surfaces for 2?+2? Cycloadditions.- 4.2 The Effect of Polarity. Potential Energy Surfaces for Nonionic and Ionic In 2?+2? Cycloadditions.- 4.3 Pericyclic, Effectively Pericyclic and Quasipericyclic Reactions.- 4.4 The Effect of Unsymmetrical Substitution and the Effect of Conjugative Substitution.- 4.5 The Regiochemistry of 2?+2? Cycloadditions.- 4.6 Isomeric Reactions and the Topochemistry of 2?+2? Cycloreversions.- 4.7 The Topochemistry of Intramolecular Cycloadditions.- 4.8 The Selectivity-PolarityRelationship.- 4.9 Reaction Intermediates and Types of Organic Mechanisms.- 4.10 2?+2? Nonionic Photocycloadditions Involving n?* Excitation.- 4.11 The Effect of Low Lying Diexcited Diabatic Surfaces in Photoreactions.- 4.12 The Problem of Energy Wastage. The Concept of Dual Channel Photoreactions.- 4.13 Generalizations.- 5. The Problem of Correlation Imposed Barriers.- 6. Reactivity Trends of Thermal Cycloadditions.- 6.1 Introduction.- 6.2 Mechanisms of Stereochemical Nonretention in Cycloadditions.- 6.3 Reactivity Trends of Thermal Nonionic 2?+2? Cycloadditions.- 6.4 Reactivity Trends of Thermal Ionic 2?+2? Cycloadditions.- 6.5 The 2?+2? Ionic Cycloaddition Problem.- 6.6 Reactivity Trends of Thermal Nonionic 4?+2? Cycloadditions.- 6.7 Reactivity Trends of Thermal Ionic 4?+2? Cycloadditions.- 7. Reactivity Trends of Singlet Photochemical Cycloadditions.- 7.1 Introduction.- 7.2 The Chorochemistry of Singlet 2?+2? Photocycloadditions.- 7.3 "Unusual" Head to Head vs. Head to Tail Regioselectivity of Photocycloadditions.- 7.4 n?* State Dual Channel Mechanisms of Polar Nonionic Carbonyl Photocycloadditions.- 7.5 ??* State Dual Channel Mechanisms of Polar Nonionic Photocycloadditions.- 8. Miscellaneous Intermolecular Multicentric Reactions.- 8.1 Cycloadditions of Cumulene Systems.- 8.2 The Ene Reaction.- 8.3 1,3 Dipolar Cycloadditions.- 9. ?? A ddition Reactions.- 9.1 Introduction.- 9.2 Potential Energy Surfaces for 2?+2? Additions.- 9.3 Reactivity Trends of 2?+2? Additions.- 10. Even-Odd Multicentric Intermolecular Reactions.- 10.1 Potential Energy Surfaces for 2?+1? Cycloadditions.- 10.2 Reactivity Trends of Cationic Even-Odd Retro-Cycloadditions and Eliminations.- 11. Potential Energy Surfaces for Odd-Odd Multicentric IntermolecularReactions.- 12. Even-Even Intermolecular Bicentric Reactions.- 12.1 Potential Energy Surfaces for Electrophilic and Nucleophilic Additions.- 12.2 Reactivity Trends of Electrophilic and Nucleophilic Substitutions.- 13. Even-Odd Intermolecular Bicentric Reactions.- 13.1 Potential Energy Surfaces for Radical Additions.- 13.2 Reactivity Trends of Radical Substitution Reactions.- 14. Odd-Odd Intermolecular Bicentric Reactions. Potential Energy Surfaces for Geometric Isomerization and Radical Combination.- 15. Odd-Odd Intramolecular Multicentric Reactions.- 15.1 Potential Energy Surfaces for Sigmatropic Shifts.- 15.2 Reactivity Trends of Sigmatropic Shifts.- 16. Even-Even Intramolecular Multicentric Reactions.- 16.1 Potential Energy Surfaces for Ionic Rearrangements.- 16.2 Reactivity Trends of Ionic Rearrangements.- 17. Mechanisms of Electrocyclic Reactions.- 17.1 Introduction.- 17.2 Reactivity Trends of Electrocyclic Reactions.- 18. Triplet Reactivity.- 18.1 Introduction.- 18.2 Excited State Spin Multiplicity and Photochemical Barrier Heights.- 18.3 The Mechanism of Spin Inversion in Triplet Nonionic Photoaromatic Reactions.- 18.4 The Mechanism of Spin Inversion in Triplet Nonionic Photoantiaromatic Reactions.- 18.5 Spin-Orbit Coupling Borrowing.- 18.6 Mechanisms of Triplet Photoreactions.- 18.7 A Model of Triplet Reactivity.- 18.8 Spin-Orbit Coupling and the Chorochemistry of Triplet Photocycloadditions.- 18.9 Spin-Orbit Coupling and the Regiochemistry of Triplet Photoaromatic Substitutions.- 19. Photophysical Processes.- 20. The Importance of Low Lying Nonvalence Orbitals.- 21. Divertissements.- 21.1 Thermal Antiaromatic Pericyclic Reactions.- 21.2 Induced Thermal Pericyclic Reactions.- 21.3 Half-Aromatic Reaction Paths.- 21.4 Ambident Reactivity.- 21.5 The Stereoselectivity of Photocycloadditions: In Search of Antiaromatic Intermediates.- 22. A Contrast of "Accepted" Concepts of Organic Reactivity and the Present Work.- Epilogue.- References.- Author Index.