Arno Behr headed the Chair of Industrial Chemistry at TU Dortmund University, Germany, until his retirement in 2017. His research interests included homogeneous transition metal catalysis, conversion of petrochemicals and renewables, and catalyst recycling.

Thomas Seidensticker leads a research group at TU Dortmund University, Germany. His research is dedicated to sustainable process design for homogeneous catalysts, including developing innovative recycling methods and converting renewable resources.

Dieter Vogt is head of the Chair of Industrial Chemistry at TU Dortmund University, Germany, since 2017. His main research interests are homogeneous transition metal catalysis, ligand and catalyst design, and process development in continuously operated miniplants.

Preface of the Authors xvii

0 Introduction: Adhering to the 12 Principles of Green Chemistry: How Does Homogeneous Catalysis Contribute? 1

Part I Chemical Basics 13

1 Definition, Variants and Examples: What Actually Is Catalysis? 15

1.1 Definition of Catalysis 15

1.2 The Different Varieties of Catalysis 18

1.3 The Directing Effect of the Catalyst 20

1.4 Sources of Information About Catalysis 21

2 A Brief History: Homogeneous Transition Metal Catalysis: A Young Science 25

2.1 Phase I: Inorganic Basic Chemicals (1898-1918) 26

2.2 Phase II: Refinery Processes: Syngas and Ethyne Chemistry (1919-1945) 27

2.3 Phase III: Petrochemical Industrial Products (1946-1970) 27

2.4 Phase IV: Fine Chemicals and Speciality Products (1971 to Date) 29

3 Industrial Homogeneous Catalysis: What Is the Economic Importance? 33

3.1 Application Areas of Catalysis 33

3.2 Important Homogeneous Catalysed Processes 33

3.3 Synthesis of Fine and Speciality Chemicals by Homogeneous Catalysis 34

3.4 Atom Economy and Environmental Factor 35

4 Definition of Important Terms: X, Y, S, STY, TON, TOF and more... 41

4.1 Conversion 42

4.2 Yield 43

4.3 Selectivity 44

4.3.1 Chemoselectivity 44

4.3.2 Regioselectivity 44

4.3.3 Diastereoselectivity 45

4.3.4 Enantioselectivity 45

4.4 Turnover Frequency 45

4.5 Turnover Number 46

4.6 Catalyst Lifetime 47

4.7 Space-Time-Yield 47

4.8 Catalyst Losses 48

4.9 Catalyst Stability/Deactivation and Recycling 49

4.10 Product Purity 49

4.11 Further Important Terms 51

4.12 The Choice Is Yours! 51

5 Basics of Organometallic Chemistry: Bonds, Elementary Steps and Mechanisms 55

5.1 Metal-Ligand Bonds 55

5.2 Change of Oxidation State (OS) 58

5.3 Change of Coordination Number (CN) and Coordination Geometry 58

5.4 The Elementary Steps 59

5.5 Catalytic Cycles 63

6 Transition Metal Compounds: The 'Captains' of Homogeneous Catalysis 67

6.1 Group 3 and Lanthanides 67

6.2 Metals of Group 4 67

6.3 MetalsofGroups5- 7 67

6.4 The 'Iron Metals' of Groups 8-10 68

6.5 The Noble Metals from Groups 8 to 10 70

6.6 Gold: A Noble Metal of Group 11 74

6.7 The Costs of Catalyst Metals 74

6.8 The Availability of Transition Metal Compounds 76

7 Ligands: The 'Helmsmen' of Homogeneous Catalysis 79

7.1 Steric Effects and Tolman's Ligand Cone Angle 80

7.2 Ligand's Electronic Effects 86

7.3 Chelating Ligands and Ligand Bite Angle 90

7.4 Hemilabile Ligands 95

7.5 Nitrogen-Based Ligands 95

7.6 Pincer Ligands 96

7.7 Ligand Syntheses 97

7.8 Ligand Stability and Decomposition 102

7.9 Costs and Accessibility of Ligands 104

8 Solvents in Homogeneous Catalysis: The Reaction Medium 107

8.1 General Aspects of Solvents 107

8.2 Physical Properties of Solvents - Solvent Parameters 108

8.3 Influence of Solvents on Homogeneous Catalysts 115

8.4 Solvent Availability and Costs 118

8.5 Solvent Purity 119

8.6 Solvent Selection Guides 120

8.7 Advanced Reaction Media for Homogeneous Catalysis 121

9 Enantioselective Catalysis: The "Special Case" 133

9.1 A Glossary of Asymmetric Catalysis 133

9.2 A Quick Look Back 136

9.3 The Mechanism of Asymmetric Catalytic Hydrogenation 139

9.4 Chiral Ligands 142

9.5 Overview of Homogeneously Catalysed Asymmetric Syntheses 143

9.6 Industrial Applications 143

10 Thermodynamics of Homogeneous Catalysis: When Does a Chemical Reaction Run? 147

10.1 Gibbs Energy and Energy Plot 147

10.2 Calculation or Assessment of the Free Reaction Enthalpy 149

10.3 Thermodynamic Analysis of Complex Reaction Systems 149

10.4 Advances in Computational Tools for Thermodynamics in Homogeneous Catalysis 151

11 Kinetics of Homogeneous Catalysis: How Does the Reaction Proceed? 159

11.1 Frequently Occurring Kinetics 159

11.2 The Use of Energy Profiles to Explain Selectivity 163

11.3 Execution of Experiments to Determine the Kinetics of a Reaction 164

11.4 A Concrete Example: Hydroformylation of Cyclooctene 165

11.5 Pitfalls in Kinetic Measurements 166

12 Overview of Spectroscopic Methods: Can We See into Homogeneous Catalysis? 169

12.1 UV/Visible Spectroscopy 170

12.2 IR Spectroscopy 171

12.3 Raman Spectroscopy 173

12.4 NMR Spectroscopy 174

12.5 Electrospray Ionisation Mass Spectroscopy (ESI-MS) 182

12.6 X-Ray Absorption Spectroscopy (XAS) and Extended X-ray absorption fine Structure Analysis (exafs) 184

12.7 Electron Paramagnetic Resonance Spectroscopy (EPR) 185

12.8 Inductively Coupled Plasma Optical Emission Spectroscopy (ICP-OES) 188

12.9 In situ, Operando and Combined Spectroscopy 189

Part II Process Engineering Fundamentals 193

13 Reactor Types: Where Homogeneous Catalysis Actually Occurs 195

13.1 Stirred Tank Reactor 195

13.2 Tubular Reactor 201

13.3 Transition variants between stirred tank reactor and plug flow reactor 202

13.4 Reactors for Gas/Liquid Reactions 203

13.5 Loop Reactors 205

13.6 Jet-Loop Reactor 205

13.7 Membrane Reactor 206

13.8 Microreactors 207

13.9 Special Reactors 208

13.10 The 'Agony of Choice' 208

14 Overview of Catalyst Separation Techniques: How Catalyst and Product Go Their Separate Ways After the Reaction 213

14.1 Separation Principles 213

14.2 Separation by Distillation 215

14.3 Separation by Precipitation 219

14.4 Separation by Crystallisation 221

14.5 Separation by Adsorption 222

14.6 Separation by Heterogenisation on a Solid Support 223

14.7 Separation by Membranes 223

14.8 Separation by Extraction 223

14.9 Separation of a Second Liquid Phase 225

15 Catalyst Separation by Membranes: A Barrier Between Products and Catalysts 229

15.1 Membranes 232

15.2 Key Figures 234

15.3 Technical Implementation 236

15.4 Industrial Applications 237

16 Immobilisation on Solid Supports: From Homogeneity to Heterogeneity 241

16.1 The Basic Principles 241

16.2 Solid-Phase Immobilisation 242

16.3 Supported-Liquid Phase (SLP) Immobilisation 246

16.4 Industrial Application 247

17 Liquid-Liquid Multiphase Systems: The Smart Approach to Catalyst Separation 249

17.1 Alteration of the Solubility of the Ligands by Selective Modifications 249

17.2 Variants of Multiphase Catalysis 251

18 Switchable Multiphase Systems: Triggering Separation of Homogeneous Mixtures 261

18.1 Temperature as a Switch 262

18.2 CO 2 Switchable Systems 270

18.3 Concluding Remarks to Recycling Methods 275

19 Optimisation Strategies: Combinatorial Synthesis, Design of Experiments and High-Throughput Screening 279

19.1 Combinatorial Chemistry 280

19.2 Design of Experiments (DoE) 283

19.3 High-Throughput Screening (HTS) 286

19.4 Virtual Screening (Computational Screening, Machine Learning) 299

20 Process Development in Miniplants: From Laboratory to Production 305

20.1 Combination of TMSs with Other Reactor Types 307

20.2 Improved Online Analytics 308

20.3 Application of TMSs for Complex Reactions in Continuous Operation 310

20.4 Combined Reaction Separation Processes 311

Part III Homogeneously Catalysed Reaction Types 315

21 An Overview of C--C-Bond Formation: A Guide Through the Jungle 319

22 Hydroformylation: The Industrial Route to Aldehydes and Alcohols 325

22.1 Main and Side Reactions 326

22.2 Catalysts 327

22.3 Mechanisms 331

22.4 Substrates 334

22.5 Asymmetric Hydroformylation 337

22.6 Syngas Surrogates 338

23 Carbonylation: The Versatile Insertions of Carbon Monoxide 341

23.1 Reactions Between CO and Hydrogen 341

23.2 Reactions of CO with Alkenes and Vinyl Arenes 343

23.3 Reactions of CO with Dienes 345

23.4 Reactions of CO with Alkynes 346

23.5 Reactions of CO with Alcohols 347

23.6 New Trends 348

24 Oligomerisation and Cyclooligomerisation: The Conversion of Unsaturated Aliphatics into Short Chains or Medium-Sized Rings 351

24.1 Oligomerisation of Alkenes 351

24.2 Dienes 359

24.3 Alkynes 361

24.4 Co-Oligomerisations 361

25 Metathesis: A 'Change-Your-Partners' Dance 365

25.1 The Many Variants of Alkene Metathesis 365

25.2 Mechanism and Catalysts 367

25.3 Industrial Applications 371

25.4 Other Types of Metatheses 373

25.5 Some Trends 375

26 Polymerisation: The Purposeful Assembly of Macromolecules 381

26.1 Polyethylene and Ziegler Catalysts 381

26.2 Polypropylene and Metallocene Catalysis 385

26.3 Further Polyalkenes and Copolymers 388

26.4 Polydienes 390

26.5 Polyketones 392

26.6 Polyalkynes 393

26.7 Post-Metallocenes 394

26.8 Some Trends 395

27 Telomerisation: The Construction of Functionalised Aliphatic Chains 397

27.1 Reactions, Mechanisms and Catalysts 397

27.2 Butadiene Telomerisation 399

27.3 Telomerisations with C 5 - and C 6 -Dienes 407

27.4 Terpenoic 1,3-Dienes 408

27.5 Enantioselective Telomerisations 408

27.6 Some Trends 409

28 Carbon-Carbon Coupling Reactions: Quite a lot of...