Overview

This book is devoted to the systematic treatment of nonequi 1 ibrium vibrational kinetics in molecular systems. Particular emphasis is given to the vibrational excitation of diatomic molecules by low-energy electrons in a discharge and by IR photons in laser-pumped systems. The book follows the different steps of the introduction, redistribution, loss, and chemical conversion of the vibrational quanta, from the points of view of the overall kinetics and the dynamics of elementary processes. These two aspects are balanced in a multidisciplinary approach. The different chapters give the basic instruments (theoretical and experimental) which are needed to understand the ki­ netics of nonequilibrium systems. The book will introduce the reader to different areas such as plasmachemistry, laser chemistry, IR and Raman spectroscopy, and relaxation phenomena, emphasizing how the vibrational energy affects such research fields. The chapters dedicated to collisional dynamics involving vibrational excited molecules provide an introduc­ tion to the modern techniques uti 1 ized in the scattering theory of inelastic and reactive collisions. The extension of the vibrational kinetics to polyatomic mole­ cules, discussed in Chap. 10, is the natural bridge between coll ision and coll i­ sionless regimes. In conclusion, we hope that the approach followed in this book will stimulate the collaboration of researchers coming from different research fields, which are too often completely separate.

Full Product Details

Author:   Mario Capitelli
Publisher:   Springer-Verlag Berlin and Heidelberg GmbH & Co. KG
Imprint:   Springer-Verlag Berlin and Heidelberg GmbH & Co. K
Edition:   Softcover reprint of the original 1st ed. 1986
Volume:   39
Dimensions:   Width: 17.00cm , Height: 1.90cm , Length: 24.40cm
Weight:   0.628kg
ISBN:  

9783642486173

ISBN 10:   3642486177
Pages:   344
Publication Date:   26 November 2012
Audience:   Professional and scholarly ,  Professional & Vocational
Format:   Paperback
Publisher's Status:   Active
Availability:   Manufactured on demand  
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Table of Contents

1. Introduction.- 1.1 Nonequilibrium Versus Equilibrium Vibrational Kinetics.- 1.2 Organization of This Book.- 2. Vibrational Kinetics, Dissociation, and Ionization of Diatomic Molecules Under Nonequilibrium Conditions.- 2.1 Laser-Induced Vibrational Kinetics.- 2.1.1 General Characteristics.- 2.1.2 Case Studies: Heteronuclear Diatomic Molecules.- 2.1.3 Homonuclear Diatomic Species.- 2.2 Nonequilibrium Vibrational Kinetics Under Electrical Discharges.- 2.2.1 General Considerations.- 2.2.2 Case Studies.- a) Nitrogen.- b) Hydrogen.- c) Carbon Monoxide.- 2.3 Post-Discharge Conditions.- 2.4 Summary.- References.- 3. Analytical Theory of Vibrational Kinetics of Anharmonic Oscillators.- 3.1 Historical Overview.- 3.2 Rate Equations and Probabilities of Elementary Processes.- 3.3 V-T Relaxation in an Inert Gas.- 3.4 Treanor Distribution in the V-V Exchange.- 3.5 V-V and V-T Exchange. Weak Excitation Regime.- 3.6 Resonance V-V Relaxation Under High-Excitation Conditions. Steady-State Conditions.- 3.7 Relaxation at Moderate Excitation of Vibrations.- 3.8 Non-Steady-State Relaxation Regime at High Excitation.- 3.9 Vibrational Kinetics and Chemical Reactions Involving Vibrational1y Excited Molecules.- 3.10 Laser Emission Excitation of Molecular Vibrations.- 3.11 Vibrational Relaxation Under Adiabatic Expansion in the Supersonic Nozzle.- 3.12 Further Studies and Outlook.- References.- 4. Vibration-Vibration and Vibration-Translation Energy Transfer, Including Multiquantum Transitions in Atom-Diatom and Diatom-Diatom Collisions.- 4.1 First-Order Theories.- 4.2 Scaling Theories.- 4.3 Semiclassical Theories.- 4.4 Analytical Expressions for V-V and V-T Rate Constants.- 4.5 Energy Transfer in Specific Systems.- 4.5.1 V-T Processes in the He + CO and CO + CO Systems.- 4.5.2 V-V Processes in CO + CO and CO + N2.- 4.A Appendix: Tables of Energy Transfer Rates in the H2 + H2, N2 + N2, He + CO, and CO + CO Systems.- References.- 5. Vibrational Energy Transfer in Collisions Involving Free Radicals.- 5.1 Mechanisms for Vibrational Relaxation.- 5.1.1 Collisions Between Species with Closed Electronic Shells.- 5.1.2 Electronically Nonadiabatic Mechanisms for Vibrational Relaxation.- 5.1.3 Vibrational Relaxation as the Result of Chemical Interaction.- 5.1.4 Summary of Vibrational Relaxation Mechanisms.- 5.2 Experimental Results and Discussion.- 5.2.1 Collisions Between Free Radicals and Noble Gas Atoms.- 5.2.2 Collisions Between Saturated Molecules in Singlet States and Radical Atoms.- a) The H3 System.- b) The H + HX (X = F, Cl) Systems.- c) The X, Y + HX (X = F, Cl, Br; Y = Cl, Br, 0) Systems.- 5.2.3 Collisions Between Unsaturated Molecules in Singlet States and Radical Atoms.- 5.2.4 Collisions Between Molecules and Molecular Free Radicals.- 5.2.5 Collisions Between Free Radicals.- 5.3 Conclusion and Prognosis.- References.- 6. Dynamics of Reactions Involving Vibrationally Excited Molecules.- 6.1 Experimental and Computational Results for Representative Atom-Diatom Reactions.- 6.1.1 Reactions of Atoms with Hydrogen Molecules and Isotopic Variants.- a) The Reaction H + H2.- b) The Reaction F + H2.- c) Reactions of Other Atoms with H2.- 6.1.2 Reactions of Atoms with Hydrogen Halides.- 6.1.3 Reactions of Atoms with Halogen and Interhalogen Molecules.- 6.1.4 Reactions of Atoms with Oxygen Molecules.- 6.1.5 Reactions Involving Other Diatomic Molecules and Ions.- 6.2 Theoretical Outlook.- 6.2.1 Coordinates for Rearrangement Processes.- 6.2.2 Decoupling Schemes for Rotations: Sudden Approximations.- 6.2.3 Hyperspherical Adiabatic Approach: Kinematic Effects for Vibrational Energy Exchange.- 6.3 Conclusions.- References.- 7. Vibrational Excitation and Dissociative Attachment.- 7.1 The Resonance Model.- 7.1.1 Qualitative Remarks.- 7.1.2 Quantitative Discussion.- 7.1.3 Cross Section for Dissociative Attachment.- 7.1.4 Cross Section for Vibrational Excitation.- 7.1.5 Semiclassical Approximation.- 7.2 Applications to Specific Molecules.- 7.2.1 Molecular Hydrogen.- a) Resonances.- b) Vibrational Excitation.- c) Dissociative Attachment.- d) Isotope Effect.- 7.2.2 Molecular Nitrogen.- a) Resonances.- b) Vibrational Excitation.- c) “Dissociative Attachment”.- 7.2.3 Carbon Monoxide.- a) Resonances.- b) Vibrational Excitation.- c) Dissociative Attachment.- 7.2.4 Hydrogen Chloride.- a) Resonances.- b) Vibrational Excitation.- c) Dissociative Attachment.- 7.3 Applications of the Attachment Process Under Nonequilibrium Conditions.- 7.3.1 Neutral Beam Injection in Fusion Plasma.- 7.3.2 Electron-Beam Switches.- 7.3.3 Laser Plasma Instabilities.- 7.3.4 Gaseous Dielectrics.- 7.A Appendix: Normalization of Continuum Functions.- References.- 8. Vibrational Distribution and Rate Constants for Vibrational Energy Transfer.- 8.1 Vibrational Distribution.- 8.1.1 The Vibrationally Excited Medium.- 8.1.2 Infrared Techniques.- a) Infrared Spontaneous Emission.- b) Probe Laser Technique.- c) Typical Results.- d) Conclusion.- 8.1.3 Light-Scattering Techniques.- a) Spontaneous Raman Scattering-Fluorescence.- b) Coherent Anti-Stokes Raman Scattering.- c) Summary.- 8.1.4 Other Techniques.- a) Multiphoton Ionization.- b) Velocity-Modulated Infrared Laser Spectroscopy.- 8.2 Rate Constants for Vibrational Energy Transfer.- 8.2.1 Steady-State Measurements.- 8.2.2 Time-Resolved Measurements.- a) Laser-Induced Infrared Fluorescence.- b) Two-Laser Experiments.- c) Other Time-Resolved Techniques.- References.- 9. Isotope Separation by Vibration-Vibration Pumping.- 9.1 Kinetic Modeling.- 9.2 Experimental Studies.- 9.2.1 Carbon Monoxide.- a) Optical Excitation.- b) Glow Discharge Excitation.- 9.2.2 Nitrogen/Oxygen Mixtures.- 9.3 V-V Pumping as an Alternative Method of Stable Isotope Preparation.- References.- 10. Vibrational Kinetics and Reactions of Polyatomic Molecules in Nonequilibrium Systems.- 10.1 Elementary Process of V-T Relaxation of Highly Excited Polyatomic Molecules.- 10.2 Elementary Process of V-V Exchange of Highly Excited Polyatomic Molecules.- 10.3 Population of Vibrationally Excited States of Polyatomic Molecules in Nonequilibrium Conditions.- 10.4 Reactions of Polyatomic Molecules Under Essentially Nonequilibrium Conditions.- 10.4.1 Fast Reactions.- 10.4.2 Slow Reactions.- 10.5 CO2 Dissociation Stimulated by Vibrational Excitation of Molecules in Plasma.- 10.5.1 Single-Temperature Approximation.- 10.5.2 Two-Temperature Approximation.- 10.6 Summary.- References.- 11. Coupling of Vibrational and Electronic Energy Distributions in Discharge and Post-Discharge Conditions.- 11.1 Coupling Between NV and the Free-Electron Energy Distribution Function.- 11.1.1 Electrical Discharges.- 11.1.2 Post-Discharge Conditions.- 11.2 Coupling Between NV and NV*.- 11.3 Conclusions.- References.- Additional References with Titles.

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