A guide to the fascinating application of CO2 as a building block in organic synthesis

This important book explores modern organic synthesis use of the cheap, non-toxic and abundant chemical CO2as an attractive C1 building block. With contributions from an international panel of experts,CO2 as a Building Block in Organic Synthesis offers a review of the most important reactions which use CO2 as a building block in organic synthesis.

The contributors examine a wide-range of CO2 reactions including methylation reactions, CH bond functionalization, carboxylation, cyclic carbonate synthesis, multicomponent reactions, and many more. The book reviews the most recent developments in the field and also:

Presents the most important reactions like CH-bond functionalization, carboxylation, carbonate synthesis and many moreContains contributions from an international panel of expertsOffers a comprehensive resource for academics and professionals in the field

Written for organic chemists, chemists working with or on organometallics, catalytic chemists, pharmaceutical chemists, and chemists in industry,CO2 as Building Block in Organic Synthesis contains an analysis of the most important reactions which use CO2 as an effective building block in organic synthesis.

Dr. Shoubhik Das in an independant group leader at the Georg-August-University of Goettingen, Germany since 2015. He has studied in India and finished his MSc from IIT Kharagpur in 2006. Subsequently, he moved to UK to join GlaxoSmithKline. In 2008, he started his PhD under the supervision of Prof. Matthias Beller at Leibniz Institut für Katalyse, Germany. In 2011, he finished his PhD and joined the research group of Prof. Matthew J. Gaunt as a post-doctoral research associate at University of Cambridge. In 2013, Dr. Das moved to EPFL, Switzerland and joined the group of Prof. Paul J. Dyson as a scientist.

1 Photochemical and SubstrateDriven CO2 Conversion 1Bart Limburg, Cristina Maquilon, and Arjan W. Kleij

1.1 Introduction 1

1.2 Iodine Activation of (Homo)Allylic Substrates 3

1.3 Substrate Activation Via Radical Addition/Photochemical Oxidation Processes 9

1.4 SubstrateInduced Activation of Oxiranes 12

1.5 SubstrateInvolved Activation of Oxetanes and Azetidines 21

1.6 Concluding Remarks 21

References 22

2 CH Carboxylations with CO2 29Uttam Dhawa, Isaac Choi, and Lutz Ackermann

2.1 Introduction 29

2.2 TransitionMetalCatalyzed CH Carboxylation 30

2.2.1 CopperCatalyzed CH Carboxylation 30

2.2.2 CobaltCatalyzed CH Carboxylation 36

2.2.3 NickelCatalyzed CH Carboxylation 36

2.2.4 MolybdenumCatalyzed CH Carboxylation 38

2.2.5 RutheniumCatalyzed CH Carboxylation 38

2.2.6 RhodiumCatalyzed CH Carboxylation 39

2.2.7 PalladiumCatalyzed CH Carboxylation 41

2.2.8 SilverCatalyzed CH Carboxylation 42

2.2.9 IridiumCatalyzed CH Carboxylation 45

2.2.10 GoldCatalyzed CH Carboxylation 45

2.2.11 NeodymiumCatalyzed CH Carboxylation 45

2.3 MetalFree CH Carboxylation 46

2.3.1 BaseMediated CH Carboxylation 46

2.3.2 ElectroCatalyzed CH Carboxylation 49

2.3.3 Lewis AcidMediated Carboxylation 49

2.3.4 LightDriven Carboxylation 50

2.4 CO2 Carboxylation Promoted by Transition Metal Complexes 52

2.5 Conclusions 53

References 53

3 TransitionMetalCatalyzed CH Carboxylation 59Joaquim Caner and Nobuharu Iwasawa

3.1 Introduction 59

3.2 Direct CH Carboxylation of ElectronDeficient Arenes and (Hetero) Arenes Catalyzed by Basic Complexes 59

3.3 Direct Carboxylation of Inert Csp2H Bonds 66

3.3.1 RhodiumCatalyzed CH Carboxylation Reactions 66

3.3.2 PalladiumCatalyzed CH Carboxylation Reactions 76

3.4 Direct Carboxylation of Csp3H Bonds 85

3.5 Summary and Outlook 89

References 90

4 Fixation of CO2 in Organic Molecules with Heterogeneous Catalysts 95Dongcheng He, Hongli Wang, and Feng Shi

4.1 Introduction 95

4.2 CO2 Cycloaddition to Epoxide 96

4.2.1 Oxides 96

4.2.2 Zeolite Catalysts 97

4.2.3 Supported Nanoparticle and Lewis Acid Catalysts 98

4.2.4 Carbon and Its Derivatives 99

4.2.5 Salen, Porphyrin, and Phthalocyanine Catalyst 101

4.2.6 Ionic Liquid Catalyst 103

4.2.7 MetalOrganic Framework (MOF) Catalyst 108

4.2.8 Bifunctional Catalyst 112

4.2.9 Other Catalysts 120

4.3 Reactions of Aziridines and CO2 120

4.4 Reactions of Polyalcohols/Olefins and CO2 121

4.5 Reaction of Propargyl Alcohols/Propargyl Amines and CO2 124

4.6 Reactions of Terminal Alkynes and CO2 125

4.7 Formylation of Amines and CO2 127

4.8 Methylation of Amines and CO2 130

4.9 Other Reactions of Amines and CO2131

4.10 Hydroformylation of CO2 and Olefins into Alcohols 133

4.11 Reactions of Aromatic Halides and CO2 134

4.12 Reactions of 2Aminobenzonitriles and CO2 136

4.13 Conclusions 137

References 138

5 CO2 Fixation into Organic Molecules via CarbonHeteroatom Bond Formation 155YuNong Li, HongRu Li and LiangNian He

5.1 Introduction 155

5.2 CO2 Conversion with CN Bond Formation 157

5.2.1 Synthesis of Oxazolidinones 157

5.2.1.1 Oxazolidinone Synthesis from Aziridine and CO2 158

5.2.1.2 Oxazolidinone Synthesis from Olefin, a Nitrogen Source, and CO2 163

5.2.1.3 Oxazolidinone Synthesis from Amino Alcohols and CO2 164

5.2.1.4 Oxazolidinone Synthesis from Carboxylative Cyclization of Propargyl Amines with CO2 165

5.2.1.5 Oxazolidinone Synthesis from Propargyl Alcohol, Aliphatic Amines/2Aminoethanols, and CO2 167

5.2.1.6 Photoinduced RadicalInitiated Carboxylative Cyclization of Allyl Amines with CO2 170

5.2.2 Synthesis of Isocyanates and Linear Carbamates 172

5.2.3 Synthesis of Urea Derivatives 174

5.2.4 Synthesis of Quinazolines 175

5.3 CO2 Conversion with CO Bond Formation 178

5.3.1 Synthesis of Cyclic Carbonates 178

5.3.1.1 Cyclic Carbonate Synthesis from Epoxide and CO2 178

5.3.1.2 Alkylidene Cyclic Carbonate Synthesis from Carboxylative Cyclization of Propargyl Alcohols with CO2 181

5.3.1.3 Cyclic Carbonate Synthesis from Carboxylative Cyclization of 1,2Diols with CO2 182

5.3.1.4 OnePot Stepwise Synthesis of Cyclic Carbonates Directly from Olefins or Vicinal Halohydrins with CO2 183

5.3.2 Synthesis of Linear Carbonates 185

5.4 CO2 Conversion with CS Bond Formation 187

5.4.1 Synthesis of Dithioacetals 187

5.4.2 Synthesis of Benzothiazolones 188

5.4.3 Synthesis of Benzothiazoles 189

5.5 CarbonHeteroatom Bond Formation from the Captured CO2 or CO2Derivatives 190

5.6 Conclusions 191

Abbreviations 192

References 193

6 CarbonylEne Reactions of Alkenes with Carbon Dioxide 199Yasuyuki Mori and Masanari Kimura

6.1 Introduction 199

6.2 CarbonylEne Reactions of Alkenes with CO2 199

6.2.1 Organoaluminum and Pyridine DerivativeMediated Coupling Reaction 199

6.2.2 LightInduced CopperCatalyzed Carboxylation of Allylic CH Bonds 204

6.2.3 Copper and Aluminum Ate Compound System for Carboxylation of Allylic CH Bond of Alkenes 208

6.2.4 CobaltCatalyzed Carboxylation of Allylic CH Bond of Terminal Alkenes 212

6.2.5 NickelCatalyzed CarbonyleneType Reaction of Terminal Alkenes with CO2 217

References 223

7 Recent Advances in Electrochemical Carboxylation of Organic Compounds for CO2 Valorization 225Luca DellAmico, Marcella Bonchio, and Xavier Companyo

7.1 Introduction 225

7.2 Electrochemical Carboxylation of Unsaturated Compounds 228

7.3 Electrochemical Carboxylation of Organic Halides 236

7.4 Stereoselective Electrochemical Carboxylations 245

7.5 Conclusions 249

References 250

8 Photocatalysis as a Powerful Tool for the Utilization of CO2 in Organic Synthesis 253Daniel Riemer and Shoubhik Das

8.1 Key Intermediate Involving Substrate with LateStage CO2 Addition/Insertion 254

8.1.1 Unsaturated Substrates 254

8.1.2 Aryl Halides 264

8.1.3 Benzylic CH Bonds 267

8.2 CO2 Substrate Adduct as the Key Intermediate 269

8.3 CO2 Radical Anion as a Key Intermediate 276

8.4 Hydroxycarbonyl Radical as a Key Intermediate 282

8.5 Conclusion and Outlook 284

References 285

9 Direct Carboxylation of Alkenes and Alkynes 291Martin Pichette Drapeau, Johannes Schranck, and Anis Tlili

9.1 Introduction 291

9.2 Carboxylation of Alkenes 291

9.2.1 Stoichiometric Carboxylation of Alkenes 291

9.2.2 Catalytic Hydrocarboxylation of Alkenes 295

9.2.3 Photoinduced Hydrocarboxylation of Alkenes 300

9.2.4 Difunctionalization of Alkenes with Carbon Dioxide 304

9.3 Carboxylation of Alkynes 305

9.3.1 Carboxylation of Terminal Alkynes 305

9.3.1.1 Synthesis of Propiolic Esters 305

9.3.1.2 Synthesis of Propiolic Acids 308

9.3.2 Synthesis of Acrylic Acid Derivatives 316

9.3.2.1 Hydrocarboxylation 316

9.3.2.2 Alkyl and Arylcarboxylations 321

9.3.2.3 Sila and Boracarboxylations 323

9.3.3 Carboxylation Leading to Cyclization Products 324

9.4 Conclusions 326

References 327

10 Homogeneous Iron Catalysts for the Synthesis of Useful Molecules from CO2331Francesco Della Monica and Carmine Capacchione

10.1 Introduction 331

10.2 Reductive Processes 332

10.2.1 Hydrogenation 332

10.2.2 Hydrosilylation and Hydroboration 335

10.2.3 Mechanistic Details 336

10.3 Nonreductive Processes 337

10.3.1 Cyclic Organic Carbonates and Aliphatic Polycarbonates from CO2and Epoxides 337

10.3.2 Mechanistic Details 346

10.3.3 Stereochemistry of Cyclic Organic Carbonates 354

10.3.4 Oxazolidinones 358

10.4 Conclusions 360

References 360

11 NHCcatalyzed CO2 Fixations in Organic Synthesis 367Vishakha Goyal, Naina Sarki, Anand Narani, and Kishore Natte

11.1 Introduction 367

11.2 Direct CH Activation with CO2 369

11.2.1 CH Activation of Terminal Alkynes 369

11.2.2 Carboxylation of Arenes and Heteroarenes 373

11.2.3 Carboxylation of Alkenes and Organoboronic Esters 376

11.3 Oxidation of Aldehydes with CO2376

11.4 Cyclization Reactions with CO2 379

11.4.1 Synthesis of Cyclic Carbonates from CO2 and Epoxides 379

11.4.2 Cyclization of CO2 in Presence of NHCCO2 Adducts 380

11.4.3 Cyclization of CO2 in Presence of Metal NHCs Complexes 382

11.4.4 Cyclization of Propargylic Amines 385

11.5 Alkylation with CO2 387

11.5.1 Nmethylation 387

11.5.2 Nformylation 388

11.6 Miscellaneous 390

11.7 Summary 393

References 393

12 SilverCatalyzed CO2 Fixation 397Kodai Saito and Tohru Yamada

12.1 Introduction 397

12.2 Historical Background of Carbon Dioxide Fixation into Organosilver Complexes 398

12.3 Carboxylation of Terminal Alkynes 399

12.4 Cascade Carboxylative Cyclization 404

12.5 SilverCatalyzed Sequential Carboxylative Cyclization of Propargyl Alcohols 405

12.6 Synthesis of Cyclic Carbonate 405

12.7 Catalytic Asymmetric Synthesis of Cyclic Carbonate 411

12.8 ThreeComponent Reaction of Propargyl Alcohols, Carbon Dioxide, and Nucleophiles 411

12.9 CO2Mediated Transformation of Propargyl Alcohols 412

12.10 Transformation of Amine Derivatives 417

12.11 Cascade Carboxylation and Cyclization of Unsaturated Amine Derivatives 417

12.11.1 Benzoxazine2one fromoAlkynylaniline and Carbon Dioxide 418

12.11.2 Cascade Carboxylation Addition to Allenes 418

12.11.3 ThreeComponent Reaction of Carbon Dioxide, Amines, and Aryloxyallens 419

12.12 Domino Carboxylation Cyclization Migration of Unsaturated Amines 421

12.12.1 Carboxylation Involving C-C Bond Formation Sequential Cyclization 423

12.12.2 Carboxylation of Enolate Sequential Cyclization 423

12.12.3 Carbon Dioxide Incorporation Reaction Using Other Carbanions 427

12.13 Carboxylation of Arylboronic Esters 428

12.13.1 Functionalization of Terminal Epoxides 431

12.14 Conclusion 432

References 433

Index 437