Homogeneous Catalysts Activity - Stability - Deactivation
, by Chadwick, John C.; Duchateau, Rob; Freixa, Zoraida; van Leeuwen, Piet W. N. M.
- ISBN: 9783527323296 | 3527323295
- Cover: Hardcover
- Copyright: 7/5/2011
This first book to illuminate this important aspect of chemical synthesis improves the lifetime of catalysts, thus reducing material and saving energy, costs and waste. The international panel of expert authors describes the studies that have been conducted concerning the way homogeneous catalysts decompose, and the differences between homogeneous and heterogeneous catalysts. The result is a ready reference for organic, catalytic, polymer and complex chemists, as well as those working in industry and with/on organometallics.
Piet van Leeuwen (1542) is groupleader at the Institute of Chemical Research of Catalonia in Tarragona, Spain, since 2004. After he received his PhD degree at Leyden University in 1967 he joined Shell Research in 1968. Until 1994 he headed a research group at Shell Research in Amsterdam, studying many aspects of homogeneous catalysis. He was Professor of Homogeneous Catalysis at the University of Amsterdam from 1989 until 2007. He has coauthored 350 publications, 30 patents, and many book chapters, and is author of the book Homogeneous Catalysis: Understanding the Art. He (co)directed 45 PhD theses. In 2005 he was awarded the Holleman Prize for organic chemistry by the Royal Netherlands Academy. In 2009 he received a doctorate honoris causa from the University Rovira I Virgili, Tarragona, and he was awarded a European Research Council Advanced Grant. John Chadwick was born in 1950 in Manchester, England and received his B.Sc. and Ph.D. degrees from the University of Bristol, after which he moved to The Netherlands, joining Shell Research in Amsterdam in 1974. He has been involved in polyolefin catalysis since the mid 1980s and in 1995 transferred from Shell to the Montell (later Basell) research center in Ferrara, Italy, where he was involved in fundamental Ziegler-Natta catalyst RD. From 2001-2009, he was at Eindhoven University of Technology on full-time secondment from Basell (now LyondellBasell Industries) to the Dutch Polymer Institute (DPI), becoming DPI Programme Coordinator for Polymer Catalysis and Immobilization. Until his retirement in 2010, his main research interests involved olefin polymerization catalysis, including the immobilization of homogeneous systems, and the relationship between catalyst and polymer structure. He is author or co-author of more than 60 publications and 11 patent applications.
| Preface | p. xi |
| Elementary Steps | p. 1 |
| Introduction | p. 1 |
| Metal Deposition | p. 2 |
| Ligand Loss | p. 2 |
| Loss of H+, Reductive Elimination of HX | p. 2 |
| Reductive Elimination of C-, N-, O-Donor Fragments | p. 5 |
| Metallic Nanoparticles | p. 6 |
| Ligand Decomposition by Oxidation | p. 7 |
| General | p. 7 |
| Oxidation | p. 7 |
| Catalysis Using O2 | p. 7 |
| Catalysis Using Hydroperoxides | p. 8 |
| Phosphines | p. 8 |
| Introduction | p. 8 |
| Oxidation of Phosphines | p. 9 |
| Oxidative Addition of a P-C Bond to a Low-Valent Metal | p. 11 |
| Nucleophilic Attack at Phosphorus | p. 16 |
| Aryl Exchange Via Phosphonium Intermediates | p. 19 |
| Aryl Exchange Via Metallophosphoranes | p. 21 |
| Phosphites | p. 23 |
| Imines and Pyridines | p. 26 |
| Carbenes | p. 27 |
| Introduction to NHCs as Ligands | p. 27 |
| Reductive Elimination of NHCs | p. 28 |
| Carbene Decomposition in Metathesis Catalysts | p. 31 |
| Reactions of Metal-Carbon and Metal-Hydride Bonds | p. 36 |
| Reactions with Protic Reagents | p. 36 |
| Reactions of Zirconium and Titanium Alkyl Catalysts | p. 37 |
| Reactions Blocking the Active Sites | p. 38 |
| Polar Impurities | p. 38 |
| Dimer Formation | p. 39 |
| Ligand Metallation | p. 40 |
| References | p. 41 |
| Early Transition Metal Catalysts for Olefin Polymerization | p. 51 |
| Ziegler-Natta Catalysts | p. 51 |
| Introduction | p. 51 |
| Effect of Catalyst Poisons | p. 52 |
| TiCl3 Catalysts | p. 53 |
| MgCl2-supported Catalysts | p. 54 |
| MgCl2/TiCl4/Ethyl Benzoate Catalysts | p. 54 |
| MgCl2/TiCl4/Diester Catalysts | p. 56 |
| MgCl2/TiCl4/Diether Catalysts | p. 57 |
| Ethene Polymerization | p. 57 |
| Metallocenes | p. 58 |
| Introduction | p. 58 |
| Metallocene/MAO Systems | p. 62 |
| Metallocene/Borate Systems | p. 66 |
| Other Single-Center Catalysts | p. 69 |
| Constrained Geometry and Half-Sandwich Complexes | p. 69 |
| Octahedral Complexes | p. 73 |
| Diamide and Other Complexes | p. 75 |
| Vanadium-Based Catalysts | p. 76 |
| Chromium-Based Catalysis | p. 80 |
| Conclusions | p. 82 |
| References | p. 83 |
| Late Transition Metal Catalysts for Olefin Polymerization | p. 91 |
| Nickel- and Palladium-based Catalysts | p. 91 |
| Diimine Complexes | p. 91 |
| Neutral Nickel(II) Complexes | p. 94 |
| Other Nickel(II) and Palladium(II) Complexes | p. 98 |
| Iron- and Cobalt-based Catalysts | p. 98 |
| Bis(imino)Pyridyl Complexes | p. 98 |
| Conclusions | p. 101 |
| References | p. 102 |
| Effects of Immobilization of Catalysts for Olefin Polymerization | p. 105 |
| Introduction | p. 105 |
| Metallocenes and Related Complexes | p. 106 |
| Immobilized MAO/Metallocene Systems | p. 106 |
| Immobilized Borane and Borate Activators | p. 109 |
| Superacidic Supports | p. 110 |
| MgCl2-Supported Systems | p. 110 |
| Other Titanium and Zirconium Complexes | p. 113 |
| Constrained Geometry Complexes | p. 113 |
| Octahedral Complexes | p. 115 |
| Vanadium Complexes | p. 117 |
| Chromium Complexes | p. 121 |
| Nickel Complexes | p. 122 |
| Iron Complexes | p. 124 |
| Conclusions | p. 225 |
| References | p. 126 |
| Dormant Species in Transition Metal-Catalyzed Olefin Polymerization | p. 132 |
| Introduction | p. 131 |
| Ziegler-Natta Catalysts | p. 132 |
| Ethene Polymerization | p. 132 |
| Propene Polymerization | p. 132 |
| Metallocenes and Related Early Transition Metal Catalysts | p. 134 |
| Cation-Anion Interactions | p. 134 |
| Effects of AlMe3 | p. 136 |
| Effects of 2,1-insertion in Propene Polymerization | p. 137 |
| Effects of ¿3-allylic Species in Propene Polymerization | p. 140 |
| Chain Epimerization in Propene Polymerization | p. 141 |
| Effects of Dormant Site Formation on Polymerization Kinetics | p. 142 |
| Late Transition Metal Catalysts | p. 143 |
| Resting States in Nickel Diimine-Catalyzed Polymerization | p. 143 |
| Effects of Hydrogen in Bis(iminopyridyl) Iron-Catalyzed Polymerization | p. 143 |
| Reversible Chain Transfer in Olefin Polymerization | p. 145 |
| Conclusions | p. 147 |
| References | p. 148 |
| Transition Metal Catalyzed Olefin Oligomerization | p. 151 |
| Introduction | p. 151 |
| Zirconium Catalysts | p. 152 |
| Titanium Catalysts | p. 153 |
| Tantalum Catalysts | p. 156 |
| Chromium Catalysts | p. 157 |
| Chromium-catalyzed Trimerization | p. 157 |
| Chromium-catalyzed Tetramerization of Ethene | p. 160 |
| Chromium-Catalyzed Oligomerization | p. 162 |
| Single-component Chromium Catalysts | p. 164 |
| Nickel Catalysts | p. 166 |
| Iron Catalysts | p. 168 |
| Tandem Catalysis involving Oligomerization and Polymerization | p. 170 |
| Conclusions | p. 171 |
| References | p. 172 |
| Asymmetric Hydrogenation | p. 177 |
| Introduction | p. 177 |
| Incubation by Dienes in Rhodium Diene Precursors | p. 179 |
| Inhibition by Substrates, Solvents, Polar Additives, and Impurities | p. 181 |
| Inhibition by Substrates: Iridium | p. 181 |
| Inhibition by Substrates, Additives: Rhodium | p. 182 |
| Inhibition by Substrates: Ruthenium | p. 187 |
| Inhibition by Formation of Bridged Species | p. 190 |
| Inhibition by Formation of Bridged Species: Iridium | p. 191 |
| Inhibition by Formation of Bridged Species: Rhodium | p. 195 |
| Inhibition by Ligand Decomposition | p. 198 |
| Inhibition by the Product | p. 199 |
| Inhibition by the Product: Rhodium | p. 199 |
| Ruthenium | p. 200 |
| Inhibition by Metal Formation; Heterogeneous Catalysis by Metals | p. 201 |
| Selective Activation and Deactivation of Enantiomeric Catalysts | p. 204 |
| Conclusions | p. 206 |
| References | p. 207 |
| Carbonylation Reactions | p. 213 |
| Introduction | p. 213 |
| Cobalt-Catalyzed Hydroformylation | p. 214 |
| Rhodium-Catalyzed Hydroformylation | p. 217 |
| Introduction of Rhodium-Catalyzed Hydroformylation | p. 217 |
| Catalyst Formation | p. 221 |
| Incubation by Impurities: Dormant Sites | p. 223 |
| Decomposition of Phosphines | p. 227 |
| Decomposition of Phosphites | p. 231 |
| Decomposition of NHCs | p. 235 |
| Two-Phase Hydroformylation | p. 238 |
| Hydroformylation by Nanoparticle Precursors | p. 244 |
| Palladium-Catalyzed Alkene-CO Reactions | p. 244 |
| Introduction | p. 244 |
| Brief Mechanistic Overview | p. 246 |
| Early Reports on Decomposition and Reactivation | p. 248 |
| Copolymerization | p. 250 |
| Methoxy- and Hydroxy-carbonylation | p. 253 |
| Methanol Carbonylation | p. 259 |
| Introduction | p. 259 |
| Mechanism and Side Reactions of the Monsanto Rhodium-Based Process | p. 260 |
| The Mechanism of the Acetic Anhydride Process Using Rhodium as a Catalyst | p. 261 |
| Phosphine-Modified Rhodium Catalysts | p. 263 |
| Iridium Catalysts | p. 265 |
| Conclusions | p. 268 |
| References | p. 269 |
| Metal-Catalyzed Cross-Coupling Reactions | p. 279 |
| Introduction; A Few Historic Notes | p. 279 |
| On the Mechanism of Initiation and Precursors | p. 283 |
| Initiation via Oxidative Addition to Pd(0) | p. 283 |
| Hydrocarbyl Pd Halide Initiators | p. 290 |
| Metallated Hydrocarbyl Pd Halide Initiators | p. 293 |
| Transmetallation | p. 299 |
| Reductive Elimination | p. 303 |
| Monodentate vs Bidentate Phosphines and Reductive Elimination | p. 303 |
| Reductive Elimination of C-F Bonds | p. 313 |
| Phosphine Decomposition | p. 316 |
| Phosphine Oxidation | p. 316 |
| P-C Cleavage of Ligands | p. 317 |
| Metal Impurities | p. 322 |
| Metal Nanoparticles and Supported Metal Catalysts | p. 327 |
| Supported Metal Catalysts | p. 327 |
| Metal Nanoparticles as Catalysts | p. 330 |
| Metal Precipitation | p. 334 |
| Conclusions | p. 334 |
| References | p. 335 |
| Alkene Metathesis | p. 347 |
| Introduction | p. 347 |
| Molybdenum and Tungsten Catalysts | p. 349 |
| Decomposition Routes of Alkene Metathesis Catalysts | p. 349 |
| Regeneration of Active Alkylidenes Species | p. 356 |
| Decomposition Routes of Alkyne Metathesis Catalysts | p. 359 |
| Rhenium Catalysts | p. 363 |
| Introduction | p. 363 |
| Catalyst Initiation and Decomposition | p. 365 |
| Ruthenium Catalysts | p. 370 |
| Introduction | p. 370 |
| Initiation and Incubation Phenomena | p. 371 |
| Decomposition of the Alkylidene Fragment | p. 376 |
| Reactions Involving the NHC Ligand | p. 379 |
| Reactions Involving Oxygenates | p. 381 |
| Tandem Metathesis/Hydrogenation Reactions | p. 385 |
| Conclusions | p. 388 |
| References | p. 390 |
| Index | p. 397 |
| Table of Contents provided by Ingram. All Rights Reserved. |
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