Description

Book Synopsis

Covers the most advanced computational and experimental methods for studying carbon-centered radical intermediates

With its focus on the chemistry of carbon-centered radicals and radical cations, this book helps readers fully exploit the synthetic utility of these intermediates in order to prepare fine chemicals and pharmaceutical products. Moreover, it helps readers better understand their role in complex atmospheric reactions and biological systems. Thoroughly up to date, the book highlights the most advanced computational and experimental methods available for studying and using these critically important intermediates.

Carbon-Centered Free Radicals and Radical Cations begins with a short history of the field of free radical chemistry, and then covers:

  • A discussion of the relevant theory

  • Mechanistic chemistry, with an emphasis on synthetic utility

  • Molecular structure and mechanism, focusing on computational method

    Trade Review
    "Overall this volume is relevant to both students and accomplished researchers alike and is highly recommended. The price is certainly affordable." (Journal of the American Chemical Society, November 2010)



    Table of Contents
    About the Volume Editor.

    Preface to Series.

    Introduction.

    Contributors.

    1. A Brief History of Carbon Radicals (Malcolm D. E. Forbes).

    2. Intermolecular Radical Additions to Alkynes: Cascade-Type Radical Cyclizations (Uta Wille).

    2.1 Introduction.

    2.2 Cascade Reactions Involving Radicals of Second Row Elements.

    2.3 Cascade Reactions Initiated by Addition of Higher Main Group (VI)-Centered Radicals to Alkynes.

    2.4 Cascade Reactions Initiated by Addition of Higher Main Group (VI)-Centered Radicals to Alkynes.

    2.5 Cascade Reactions Initiated by Addition of Higher Main Group (V)-Centered Radicals to Alkynes.

    3. Radical Cation Fragmentation Reactions in Organic Synthesis (Alexander J. Poniatowski and Paul E. Floreancig).

    3.1 Introduction.

    3.2 Electron Transfer-Initiated Cyclization Reactions.

    3.3 Oxidative Acyliminium Ion Formation.

    3.4 Carbon–Carbon Bond Formation.

    3.5 Summary and Outlook.

    4. Selectivity in Radical Cation Cycloadditions (Christo S. Sevov and Olaf Wiest).

    4.1 Introduction.

    4.2 Mechanism and the Origin of the Rate Acceleration.

    4.3 Selectivity in Radical Cation Cycloadditions.

    4.4 Chemoselectivity.

    4.5 Regioselectivity.

    4.6 Periselectivity.

    4.7 Endo/Exo Selectivity.

    4.8 Conclusions.

    5. The Stability of Carbon-Centered Radicals (Michelle L. Coote, Ching Yeh Lin, and Hendrik Zipse).

    5.1 Introduction.

    5.2 Theoretical Methods.

    5.3 RSE Values for Carbon-Centered Radicals.

    5.4 Use of RSE Values in Practical Applications.

    5.5 Conclusions.

    6. Interplay of Stereoelectronic Vibrational and Environmental Effects in Tuning Physicochemical Properties of Carbon-Centered Radicals (Vincenzo Barone, Malgorzata Biczysko, and Paola Cimino).

    6.1 Introduction.

    6.2 EPR Spectroscopy.

    6.3 Calculation of EPR Parameters.

    6.4 Vibrational Properties Beyond the Harmonic Approximation.

    6.5 Electronic Properties: Vertical Excitation Energies, Structure, and Frequencies in Excited Electronic States.

    6.6 Vibronic Spectra.

    6.7 Concluding Remarks.

    7. Unusual Structures of Radical Ions in Carbon Skeletons: Nonstandard Chemical Bonding by Restricting Geometries (Georg Gescheidt).

    7.1 Introduction.

    7.2 The Tools.

    7.3 Pagodane and Its Derivatives.

    7.4 Different Stages of Cycloaddition/Cycloreversion Reactions Within Confined Environments.

    7.5 Extending the ‘‘Cage Concept’’.

    7.6 Summary.

    8. Magnetic Field Effects on Radical Pairs in Homogeneous Solution (Jonathan. R. Woodward).

    8.1 Introduction.

    8.2 The Spin-Correlated Radical Pair.

    8.3 Application of a Magnetic Field.

    8.4 Spin-State Mixing.

    8.5 The Magnetic Field Dependence of Radical Pair Reactions.

    8.6 Theoretical Approaches.

    8.7 Experimental Approaches.

    8.8 The Life Cycle of Radical Pairs in Homogeneous Solution.

    8.9 Summary.

    9. Chemical Transformations Within the Paramagnetic World Investigated by Photo-CIDNP (Martin Goez).

    9.1 Introduction.

    9.2 CIDNP Theory.

    9.3 Experimental Methods.

    9.4 Radical—Radical Transformations During Diffusive Excursions.

    9.5 Radical—Radical Transformations at Reencounters.

    9.6 Interconversions of Biradicals.

    9.7 Conclusions.

    10. Spin Relaxation in Ru-Chromophore-Linked Azine/Diquat Radical Pairs (Matthew T. Rawls, Ilya Kuprov, C. Michael Elliott, and Ulrich E. Steiner).

    10.1 Introduction.

    10.2 EPR for the Isolated Ions.

    10.3 Calculation Methods for EPR of the Isolated Ions.

    10.4 Implications for Spin-Relaxation in Linked Radical Pairs.

    11. Reaction Dynamics of Carbon-Centered Radicals in Extreme Environments Studied by the Crossed Molecular Beam Technique (Ralf I. Kaiser).

    11.1 Introduction.

    11.2 The Crossed Molecular Beam Method.

    11.3 Experimental Setup.

    11.4 Crossed Beam Studies.

    11.5 Conclusions.

    12. Laser Flash Photolysis of Photoinitiators: ESR, Optical, and IR Spectroscopy Detection of Transients (Igor V. Khudyakov and Nicholas J. Turro).

    12.1 Introduction.

    12.2 Photodissociation of Initiators.

    12.3 TR ESR Detection of Transients.

    12.4 Optical Detection of Transients.

    12.5 IR Detection of Free Radicals and Monitoring Their Reactions.

    12.6 Concluding Remarks.

    13. Dynamics of Radical Pair Processes in Bulk Polymers (Carlos A. Chesta and Richard G. Weiss).

    13.1 Introduction.

    13.2 Singlet-State Radical Pairs from Irradiation of Aryl Esters and Alkyl Aryl Ethers.

    13.2.1 General Mechanistic Considerations From Solution and Gas-Phase Studies.

    13.3 Photo-Reactions of Aryl Esters in Polymer Matrices. Kinetic Information from Constant Intensity Irradiations.

    13.4 Rate Information from Constant Intensity Irradiation of Alkyl Aryl Ethers.

    13.5 Comparison of Calculated Rates to Other Methods for Polyethylene Films.

    13.6 Triplet-State Radical Pairs.

    13.7 Concluding Remarks.

    14. Acrylic Polymer Radicals: Structural Characterization and Dynamics (Malcolm D. E. Forbes and Natalia V. Lebedeva).

    14.1 Introduction.

    14.2 The Photodegradation Mechanism.

    14.3 Polymer Structures.

    14.4 The Time-Resolved EPR Experiment.

    14.5 Tacticity and Temperature Dependence of Acrylate Radicals.

    14.6 Structural Dependence.

    14.7 Oxo-Acyl Radicals.

    14.8 Spin Polarization Mechanisms.

    14.9 Solvent Effects.

    14.10 Dynamic Effects.

    14.11 Conclusions.

    Index.

CarbonCentered Free Radicals and Radical Cations

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    A Hardback by Malcolm D. Forbes

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      View other formats and editions of CarbonCentered Free Radicals and Radical Cations by Malcolm D. Forbes

      Publisher: John Wiley & Sons Inc
      Publication Date: 05/03/2010
      ISBN13: 9780470390092, 978-0470390092
      ISBN10: 0470390093
      Also in:
      Chemistry

      Description

      Book Synopsis

      Covers the most advanced computational and experimental methods for studying carbon-centered radical intermediates

      With its focus on the chemistry of carbon-centered radicals and radical cations, this book helps readers fully exploit the synthetic utility of these intermediates in order to prepare fine chemicals and pharmaceutical products. Moreover, it helps readers better understand their role in complex atmospheric reactions and biological systems. Thoroughly up to date, the book highlights the most advanced computational and experimental methods available for studying and using these critically important intermediates.

      Carbon-Centered Free Radicals and Radical Cations begins with a short history of the field of free radical chemistry, and then covers:

      • A discussion of the relevant theory

      • Mechanistic chemistry, with an emphasis on synthetic utility

      • Molecular structure and mechanism, focusing on computational method

        Trade Review
        "Overall this volume is relevant to both students and accomplished researchers alike and is highly recommended. The price is certainly affordable." (Journal of the American Chemical Society, November 2010)



        Table of Contents
        About the Volume Editor.

        Preface to Series.

        Introduction.

        Contributors.

        1. A Brief History of Carbon Radicals (Malcolm D. E. Forbes).

        2. Intermolecular Radical Additions to Alkynes: Cascade-Type Radical Cyclizations (Uta Wille).

        2.1 Introduction.

        2.2 Cascade Reactions Involving Radicals of Second Row Elements.

        2.3 Cascade Reactions Initiated by Addition of Higher Main Group (VI)-Centered Radicals to Alkynes.

        2.4 Cascade Reactions Initiated by Addition of Higher Main Group (VI)-Centered Radicals to Alkynes.

        2.5 Cascade Reactions Initiated by Addition of Higher Main Group (V)-Centered Radicals to Alkynes.

        3. Radical Cation Fragmentation Reactions in Organic Synthesis (Alexander J. Poniatowski and Paul E. Floreancig).

        3.1 Introduction.

        3.2 Electron Transfer-Initiated Cyclization Reactions.

        3.3 Oxidative Acyliminium Ion Formation.

        3.4 Carbon–Carbon Bond Formation.

        3.5 Summary and Outlook.

        4. Selectivity in Radical Cation Cycloadditions (Christo S. Sevov and Olaf Wiest).

        4.1 Introduction.

        4.2 Mechanism and the Origin of the Rate Acceleration.

        4.3 Selectivity in Radical Cation Cycloadditions.

        4.4 Chemoselectivity.

        4.5 Regioselectivity.

        4.6 Periselectivity.

        4.7 Endo/Exo Selectivity.

        4.8 Conclusions.

        5. The Stability of Carbon-Centered Radicals (Michelle L. Coote, Ching Yeh Lin, and Hendrik Zipse).

        5.1 Introduction.

        5.2 Theoretical Methods.

        5.3 RSE Values for Carbon-Centered Radicals.

        5.4 Use of RSE Values in Practical Applications.

        5.5 Conclusions.

        6. Interplay of Stereoelectronic Vibrational and Environmental Effects in Tuning Physicochemical Properties of Carbon-Centered Radicals (Vincenzo Barone, Malgorzata Biczysko, and Paola Cimino).

        6.1 Introduction.

        6.2 EPR Spectroscopy.

        6.3 Calculation of EPR Parameters.

        6.4 Vibrational Properties Beyond the Harmonic Approximation.

        6.5 Electronic Properties: Vertical Excitation Energies, Structure, and Frequencies in Excited Electronic States.

        6.6 Vibronic Spectra.

        6.7 Concluding Remarks.

        7. Unusual Structures of Radical Ions in Carbon Skeletons: Nonstandard Chemical Bonding by Restricting Geometries (Georg Gescheidt).

        7.1 Introduction.

        7.2 The Tools.

        7.3 Pagodane and Its Derivatives.

        7.4 Different Stages of Cycloaddition/Cycloreversion Reactions Within Confined Environments.

        7.5 Extending the ‘‘Cage Concept’’.

        7.6 Summary.

        8. Magnetic Field Effects on Radical Pairs in Homogeneous Solution (Jonathan. R. Woodward).

        8.1 Introduction.

        8.2 The Spin-Correlated Radical Pair.

        8.3 Application of a Magnetic Field.

        8.4 Spin-State Mixing.

        8.5 The Magnetic Field Dependence of Radical Pair Reactions.

        8.6 Theoretical Approaches.

        8.7 Experimental Approaches.

        8.8 The Life Cycle of Radical Pairs in Homogeneous Solution.

        8.9 Summary.

        9. Chemical Transformations Within the Paramagnetic World Investigated by Photo-CIDNP (Martin Goez).

        9.1 Introduction.

        9.2 CIDNP Theory.

        9.3 Experimental Methods.

        9.4 Radical—Radical Transformations During Diffusive Excursions.

        9.5 Radical—Radical Transformations at Reencounters.

        9.6 Interconversions of Biradicals.

        9.7 Conclusions.

        10. Spin Relaxation in Ru-Chromophore-Linked Azine/Diquat Radical Pairs (Matthew T. Rawls, Ilya Kuprov, C. Michael Elliott, and Ulrich E. Steiner).

        10.1 Introduction.

        10.2 EPR for the Isolated Ions.

        10.3 Calculation Methods for EPR of the Isolated Ions.

        10.4 Implications for Spin-Relaxation in Linked Radical Pairs.

        11. Reaction Dynamics of Carbon-Centered Radicals in Extreme Environments Studied by the Crossed Molecular Beam Technique (Ralf I. Kaiser).

        11.1 Introduction.

        11.2 The Crossed Molecular Beam Method.

        11.3 Experimental Setup.

        11.4 Crossed Beam Studies.

        11.5 Conclusions.

        12. Laser Flash Photolysis of Photoinitiators: ESR, Optical, and IR Spectroscopy Detection of Transients (Igor V. Khudyakov and Nicholas J. Turro).

        12.1 Introduction.

        12.2 Photodissociation of Initiators.

        12.3 TR ESR Detection of Transients.

        12.4 Optical Detection of Transients.

        12.5 IR Detection of Free Radicals and Monitoring Their Reactions.

        12.6 Concluding Remarks.

        13. Dynamics of Radical Pair Processes in Bulk Polymers (Carlos A. Chesta and Richard G. Weiss).

        13.1 Introduction.

        13.2 Singlet-State Radical Pairs from Irradiation of Aryl Esters and Alkyl Aryl Ethers.

        13.2.1 General Mechanistic Considerations From Solution and Gas-Phase Studies.

        13.3 Photo-Reactions of Aryl Esters in Polymer Matrices. Kinetic Information from Constant Intensity Irradiations.

        13.4 Rate Information from Constant Intensity Irradiation of Alkyl Aryl Ethers.

        13.5 Comparison of Calculated Rates to Other Methods for Polyethylene Films.

        13.6 Triplet-State Radical Pairs.

        13.7 Concluding Remarks.

        14. Acrylic Polymer Radicals: Structural Characterization and Dynamics (Malcolm D. E. Forbes and Natalia V. Lebedeva).

        14.1 Introduction.

        14.2 The Photodegradation Mechanism.

        14.3 Polymer Structures.

        14.4 The Time-Resolved EPR Experiment.

        14.5 Tacticity and Temperature Dependence of Acrylate Radicals.

        14.6 Structural Dependence.

        14.7 Oxo-Acyl Radicals.

        14.8 Spin Polarization Mechanisms.

        14.9 Solvent Effects.

        14.10 Dynamic Effects.

        14.11 Conclusions.

        Index.

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