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More About This Title Understanding Organometallic Reaction Mechanismsand Catalysis - Computational and ExperimentalTools
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The latest insights and developments in the mechanistic studies of organometallic reactions and catalytic processes are presented and reviewed. The book adopts a unique approach, exemplifying how to use experiments, spectroscopy measurements, and computational methods to reveal reaction pathways and molecular structures of catalysts, rather than concentrating solely on one discipline. The result is a deeper understanding of the underlying reaction mechanism and correlation between molecular structure and reactivity. The contributions represent a wealth of first-hand information from renowned experts working in these disciplines, covering such topics as activation of small molecules, C-C and C-Heteroatom bonds formation, cross-coupling reactions, carbon dioxide converison, homogeneous and heterogeneous transition metal catalysis and metal-graphene systems. With the knowledge gained, the reader will be able to improve existing reaction protocols and rationally design more efficient catalysts or selective reactions.
An indispensable source of information for synthetic, analytical, and theoretical chemists in academia and industry.
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Valentine Ananikov was a recipient of the Russian State Prize for Outstanding Achievements in Science and Technology in 2004, a Science Support Foundation award in 2005, a Russian Academy of Sciences Medal in 2000. He was named a Liebig Lecturer by German Chemical Society in 2010, and was awarded the Balandin Prize for outstanding achievements in the field of catalysis in 2010. His scientific interests are focused on development of new concepts in transition metal and nanoparticle catalysis, sustainable organic synthesis and new methodology for mechanistic studies of complex chemical transformations. His research has been supported by grants of Russian Science Foundation, Russian Foundation of Basic Research and Grants of President of Russia.
Valentine Ananikov is a member of the International Advisory Boards of Advanced Synthesis & Catalysis, Organometallics, Chemistry - An Asian Journal and OpenChemistry.
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List of Contributors XI
Preface XV
1 Mechanisms of Metal-Mediated C–N Coupling Processes: A Synergistic Relationship between Gas-Phase Experiments and Computational Chemistry 1
Robert Kretschmer, Maria Schlangen, and Helmut Schwarz
1.1 Introduction 1
1.2 From Metal-Carbon to Carbon–Nitrogen Bonds 2
1.2.1 Thermal Reactions of Metal Carbide and Metal Methylidene Complexes with Ammonia 2
1.2.2 How Metals Control the C–N Bond-Making Step in the Coupling of CH4 and NH3 4
1.2.3 C–N Coupling via SN2 Reactions: Neutral Metal Atoms as a Novel Leaving Group 6
1.3 From Metal-Nitrogen to Carbon-Nitrogen Bonds 8
1.3.1 High-Valent Iron Nitride and Iron Imide Complexes 8
1.3.2 Metal-Mediated Hydroamination of an Unactivated Olefin by [Ni(NH2)]+ 11
1.4 Conclusion and Perspectives 12
Acknowledgments 14
References 14
2 Fundamental Aspects of theMetal-Catalyzed C–H Bond Functionalization by Diazocarbenes: Guiding Principles for Design of Catalyst with Non-redox-Active Metal (Such as Ca) and Non-Innocent Ligand 17
Adrian Varela-Alvarez and Djamaladdin G. Musaev
2.1 Introduction 17
2.1.1 Electronic Structure of Free Carbenes 20
2.1.2 Electronic Structure of Metallocarbenes 22
2.2 TheoreticalModels andMethods 25
2.3 Design of Catalyst with Non-redox-Active Metal and Non-Innocent Ligand 26
2.3.1 The Proposed Catalyst: a Coordinatively Saturated Ca(II) Complex 26
2.3.2 Potential Energy Surface of the [(PDI)Ca(THF)3] Catalyzed C–H Bond Alkylation of MeCH2Ph by Unsubstituted N2CH2 Diazocarbene 27
2.3.3 [(PDI)Ca(THF)3]-Catalyzed C–H Bond Alkylation of MeCH2Ph by Donor–Donor (D/D) Diazocarbene N2CPh2 32
2.4 Conclusions and Perspectives 35
Acknowledgment 37
References 37
3 Using Metal Vinylidene Complexes to Probe the Partnership Between Theory and Experiment 41
John M. Slattery, Jason M. Lynam, and Natalie Fey
3.1 Introduction 41
3.1.1 The Partnership between Theory and Experiment 41
3.1.2 Transition-Metal-Stabilized Vinylidenes 42
3.2 Project Planning in Organometallic Chemistry 44
3.2.1 Experimental Methodologies 44
3.2.2 Computational Methodologies 46
3.3 Case Studies 49
3.3.1 Mechanism of Rhodium-Mediated Alkyne to Vinylidene Transformation 50
3.3.2 Using Ligand Assistance to Form Ruthenium–Vinylidene Complexes 54
3.3.3 Vinylidenes in Gold Catalysis 58
3.3.4 Metal Effects on the Alkyne/Vinylidene Tautomer Preference 61
3.4 The Benefits of Synergy and Partnerships 63
References 64
4 Ligand, Additive, and Solvent Effects in Palladium Catalysis – Mechanistic Studies En Route to Catalyst Design 69
Franziska Schoenebeck
4.1 Introduction 69
4.2 The Effect of Solvent in Palladium-Catalyzed Cross Coupling and on the Nature of the Catalytically Active Species 71
4.3 Common Additives in Palladium-Catalyzed Cross-Coupling Reactions – Effect on (Pre)catalyst and Active Catalytic Species 75
4.4 Pd(I) Dimer: Only Precatalyst or Also Catalyst? 79
4.5 Investigation of Key Catalytic Intermediates in High-Oxidation-State Palladium Chemistry 81
4.6 Concluding Remarks 87
References 88
5 Computational Studies on Sigmatropic Rearrangements via Pi-Activation by Palladium and Gold Catalysts 93
Osvaldo Gutierrez and Marisa C. Kozlowski
5.1 Introduction 93
5.1.1 Sigmatropic Rearrangements 93
5.1.2 Metal-Catalyzed Sigmatropic Rearrangements 93
5.2 Palladium as a Catalyst 94
5.2.1 Palladium Alkene Activation 94
5.2.2 Palladium Alkyne Activation 103
5.3 Gold as a Catalyst 103
5.3.1 Gold Alkene Activation 103
5.3.2 Gold Alkyne Activation 108
5.4 Concluding Remarks 117
References 117
6 Theoretical Insights into Transition Metal-Catalyzed Reactions of Carbon Dioxide 121
Ting Fan and Zhenyang Lin
6.1 Introduction 121
6.2 Theoretical Methods 122
6.3 Hydrogenation of CO2 with H2 122
6.4 Coupling Reactions of CO2 and Epoxides 127
6.5 Reduction of CO2 with Organoborons 131
6.6 Carboxylation of Olefins with CO2 134
6.7 Hydrocarboxylation of Olefins with CO2 and H2 134
6.8 Summary 137
Acknowledgment 139
References 139
7 Catalytically Enhanced NMR of Heterogeneously Catalyzed Hydrogenations 145
Vladimir V. Zhivonitko, Kirill V. Kovtunov, Ivan V. Skovpin, Danila A. Barskiy, Oleg G. Salnikov, and Igor V. Koptyug
7.1 Introduction 145
7.2 Parahydrogen and PHIP Basics 146
7.3 PHIP as a Mechanistic Tool in Homogeneous Catalysis 149
7.3.1 PHIP-Enhanced NMR of Reaction Products 150
7.3.2 PHIP Studies of Reaction Intermediates 152
7.3.3 Activation of H2 and Structure and Dynamics of Metal Dihydride Complexes 153
7.4 PHIP-Enhanced NMR and Heterogeneous Catalysis 155
7.4.1 PHIP with Immobilized Metal Complexes 155
7.4.2 PHIP with Supported Metal Catalysts 164
7.4.3 Model Calculations Related to Underlying Chemistry in PHIP 173
7.5 Summary and Conclusions 180
Acknowledgments 180
References 181
8 Combined Use of Both Experimental and Theoretical Methods in the Exploration of Reaction Mechanisms in Catalysis by Transition Metals 187
Daniel Lupp, Niels Johan Christensen, and Peter Fristrup
8.1 Introduction 187
8.1.1 Hammett Methodology 187
8.1.2 Kinetic Isotope Effects 188
8.1.3 Competition Experiments 189
8.2 Recent DFT Developments of Relevance to Transition Metal Catalysis 190
8.2.1 Computational Efficiency 191
8.2.2 Dispersion Effects 193
8.2.3 Solvation 195
8.2.4 Effective Core Potentials 196
8.2.5 Connecting Theory with Experiment 197
8.3 Case Studies 197
8.3.1 Rhodium-Catalyzed Decarbonylation of Aldehydes 198
8.3.2 Iridium-Catalyzed Alkylation of Alcohols with Amines 203
8.3.3 Palladium-Catalyzed Allylic C–H Alkylation 205
8.3.4 Ruthenium-Catalyzed Amidation of Alcohols 209
8.4 Conclusions 213
Acknowledgments 214
References 214
9 Is There Something New Under the Sun? Myths and Facts in the Analysis of Catalytic Cycles 217
Sebastian Kozuch
9.1 Introduction 217
9.1.1 Prologue 217
9.1.2 A Brief History of Catalysis 217
9.2 Kinetics Based on Rate Constants or Energies 218
9.2.1 Kinetic Graphs 220
9.2.2 TOF Calculation of Any Cycle 222
9.2.3 TOF in the E-Representation 225
9.3 Application: Cross-Coupling with a Bidentate Pd Complex 227
9.4 A Century of Sabatier’s Genius Idea 230
9.5 Theory and Practice of Catalysis, Including Concentration Effects 232
9.5.1 Application: Negishi Cross-Coupling with a Ni Complex 233
9.5.2 Can a Reaction Be Catalyzed in Both Directions? 236
9.5.3 The Power Law 239
9.6 RDStep, RDStates 239
9.6.1 Finding the RDStates 242
9.6.2 Finding the Irreversible Steps 243
9.7 Conclusion 244
9.7.1 The Last Myth: Defining the TOF 244
9.7.2 FinalWords about the E-Representation 245
References 246
10 Computational Tools for Structure, Spectroscopy and Thermochemistry 249
Vincenzo Barone, Malgorzata Biczysko, and Ivan Carnimeo
10.1 Introduction 249
10.2 Basic Concepts 251
10.2.1 Potential Energy Surface: Molecular Structure, Transition States, and Reaction Paths 251
10.2.2 DFT and Hybrid Approaches for Organometallic Systems 254
10.2.3 Description of Environment 257
10.3 Spectroscopic Techniques 260
10.3.1 Rotational Spectroscopy 261
10.3.3 Electronic Spectroscopy 280
10.4 Applications and Case Studies 287
10.4.1 Thermodynamics and Vibrational Spectroscopy Beyond Harmonic Approximation: Glycine and Its Metal Complexes 287
10.4.2 Optical Properties of Organometallic Systems 297
10.4.3 Interplay of Different Effects: The Case of Chlorophyll-a 302
10.5 Conclusions and Future Developments 308
Acknowledgments 309
References 309
11 ComputationalModeling of Graphene Systems Containing Transition Metal Atoms and Clusters 321
Mikhail V. Polynski and Valentine P. Ananikov
11.1 Introduction 321
11.2 Quantum Chemical Modeling and Benchmarking 322
11.2.1 Electron Correlation Methods 322
11.2.2 Dispersion-Accounting DFT Methods 324
11.2.3 Database and Benchmarking Considerations 334
11.2.4 Outlook on Database and Benchmarking 340
11.3 Representative Studies of Graphene Systems with Transition Metals 341
11.3.1 Graphene Models 341
11.3.2 Pristine Graphene as a Substrate for Transition Metal Particles 342
11.3.3 Defective or Doped Graphene as a Support for Transition Metal Particles 347
11.3.4 Studies of Complex Graphene Systems with Transition Metals 352
11.3.5 Modeling Chemical Transformations in Graphene/Transition Metal Systems 355
11.4 Conclusions 362
Acknowledgments 363
List of Abbreviations 363
References 365
Index 375