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BuchGebunden
464 Seiten
Englisch
Wiley-VCHerschienen am30.04.20241. Auflage
Green Solvents in Organic Synthesis Essential reference on replacing conventional solvents with greener alternatives in industrial chemicals synthesis and production A well-timed book promoting sustainability in synthesis and production of chemicals, Green Solvents in Organic Synthesis details various green solvents, solvent systems, and solubilization techniques, including their chemistry, physiochemical properties, performance, and distinct applications, presenting a greener approach to conventional solvents by replacing them with sustainable alternatives that have similarities in their reaction mechanisms. Edited by four highly qualified academics with significant research experience in the field, Green Solvents in Organic Synthesis includes information on: Water and liquid polymers (Polyethylene glycol PEG), Acetonitrile, DMSO, Dimethyl carbonate, Ionic liquids, and Supercritical fluids)Bio-based solvents (Cyrene, γ-Valerolactone (GVL), Lactic acid, 2-MeTHF) and deep eutectic solvents (DESs)Alcohols (MeOH, EtOH, i-PrOH, n-BuOH, t-BuOH, Ethylene glycol), ketones (Acetones, MEK, MIBK, Cyclohexanone), and esters (Methyl acetate, Ethyl acetate, i-PrOAc, n-BuOAc)Technical, economic, and environmental aspects of green solvents and how to maximize their reuse and recycling to alleviate pollution and reduce energy consumption For chemists in a variety of disciplines, Green Solvents in Organic Synthesis is an essential reference that provides foundational knowledge of green solvents, along with key features of each class of green solvent within the context of organic reactions for industrial and laboratory synthesis.mehr
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Produkt

KlappentextGreen Solvents in Organic Synthesis Essential reference on replacing conventional solvents with greener alternatives in industrial chemicals synthesis and production A well-timed book promoting sustainability in synthesis and production of chemicals, Green Solvents in Organic Synthesis details various green solvents, solvent systems, and solubilization techniques, including their chemistry, physiochemical properties, performance, and distinct applications, presenting a greener approach to conventional solvents by replacing them with sustainable alternatives that have similarities in their reaction mechanisms. Edited by four highly qualified academics with significant research experience in the field, Green Solvents in Organic Synthesis includes information on: Water and liquid polymers (Polyethylene glycol PEG), Acetonitrile, DMSO, Dimethyl carbonate, Ionic liquids, and Supercritical fluids)Bio-based solvents (Cyrene, γ-Valerolactone (GVL), Lactic acid, 2-MeTHF) and deep eutectic solvents (DESs)Alcohols (MeOH, EtOH, i-PrOH, n-BuOH, t-BuOH, Ethylene glycol), ketones (Acetones, MEK, MIBK, Cyclohexanone), and esters (Methyl acetate, Ethyl acetate, i-PrOAc, n-BuOAc)Technical, economic, and environmental aspects of green solvents and how to maximize their reuse and recycling to alleviate pollution and reduce energy consumption For chemists in a variety of disciplines, Green Solvents in Organic Synthesis is an essential reference that provides foundational knowledge of green solvents, along with key features of each class of green solvent within the context of organic reactions for industrial and laboratory synthesis.
Details
ISBN/GTIN978-3-527-35200-5
ProduktartBuch
EinbandartGebunden
Verlag
Erscheinungsjahr2024
Erscheinungsdatum30.04.2024
Auflage1. Auflage
Seiten464 Seiten
SpracheEnglisch
Gewicht1034 g
Illustrationen200 SW-Abb., 200 Farbabb.
Artikel-Nr.54926227

Inhalt/Kritik

Inhaltsverzeichnis
1 Recent Achievements in Organic Reactions in Alcohols 1 Lan Zhao, Man Zhao, Meng-Ge Wei, Hong-Ru Li, and Liang-Nian He 1.1 Introduction 1 1.2 Alcohols as Green Solvents 6 1.2.1 Hydrogenation/Reduction Reaction 6 1.2.2 Oxidation Reaction 8 1.2.3 Substitution Reaction 10 1.2.4 Addition Reaction 11 1.2.5 Cyclization Reaction 13 1.2.6 Coupling Reaction 18 1.2.7 Condensation/Ring Condensation Reaction 21 1.3 Alcohols as Green Solvents and Catalysts 28 1.3.1 Addition Reaction 28 1.3.2 Cyclization Reaction 28 1.3.3 Coupling Reaction 30 1.3.4 Condensation Reaction 30 1.3.5 Metathesis Reaction 35 1.4 Alcohols as Green Solvents and Hydrogen Donors 35 1.5 Miscellaneous 39 1.5.1 Polyethylene Glycol as a Solvent for CO 2 Capture and Conversion 39 1.5.2 Polyethylene Glycol Radical-Initiated Oxidation Reactions in Compressed Carbon Dioxide 41 1.5.3 Ring-Opening Reaction 43 1.6 Summary and Concluding Remarks 45 Acknowledgments 46 References 46 2 Recent Achievements in Organic Reactions in MeCN 51 Tongtong Xing, Guizhi Zhai, Linna Wu, Xiaofen Wang, and Zechao Wang 2.1 Introduction 51 2.2 MeCN in Transition Metal-catalyzed Reactions Without Radicals Involved 52 2.2.1 Transition Metal-catalyzed Addition Reactions in MeCN 52 2.2.2 Transition Metal-catalyzed Oxidation Reactions in MeCN 56 2.2.3 Transition Metal-catalyzed Reduction Reactions in MeCN 64 2.2.4 Transition Metal-catalyzed Substitution Reactions in MeCN 66 2.2.5 Transition Metal-catalyzed Cyclization Reactions in MeCN 74 2.3 MeCN in Transition Metal-free Catalyzed Reactions Without Radicals Involved 80 2.3.1 Transition Metal-free Catalyzed Cyclization Reactions in MeCN 80 2.3.2 Transition Metal-free Catalyzed Multicomponent Reactions in MeCN 84 2.3.3 Transition Metal-free Catalyzed C-X Bond Formation in MeCN 87 2.4 MeCN in C-X Bonds Formation With Radicals Involved 90 2.4.1 C-C, C-Si Bond Formation in MeCN 90 2.4.2 C-N, C-P Bond Formation in MeCN 93 2.4.3 C-O, C-S Bond Formation in MeCN 96 2.4.4 C-Halogen Bond Formation in MeCN 98 2.5 Conclusion 102 References 102 3 Recent Achievements in Organic Reactions in Bio-based Solvents 107 Shaomin Chen, Noman Haider Tariq, and Yanlong Gu 3.1 Introduction 107 3.2 Glycerol 108 3.3 Polyethylene Glycols (PEGs) 112 3.4 2-Methyltetrahydrofuran (2-MeTHF) 114 3.5 Cyclopentyl Methyl Ether (CPME) 117 3.6 Organic Carbonates 120 3.7 γ-Valerolactone (GVL) 125 3.8 Ethyl Lactate (EL) 128 3.9 Miscellaneous 130 3.10 Conclusions and Outlook 131 References 131 4 Recent Achievements in Organic Reactions in DMSO 137 Peng Yuan, Jia-Chen Xiang, and An-Xin Wu 4.1 Pummerer-type Activation of DMSO 138 4.2 Selectfluor-enabled Activation of DMSO 148 4.3 Activation of DMSO Enabled by Single-electron Transformation 151 4.4 Electrocatalytic Synthesis Enabled Activation of DMSO 163 4.5 Photocatalytic Reaction Enabled Activation of DMSO 164 4.6 DMSO Acts as the Metal Ligand 171 4.7 Some Special Activation or Usage of DMSO 174 4.8 Summary and Outlook 181 References 181 5 The Use of DMC as Green Solvent in Organic Synthesis 185 Xinxin Qi and Xiao-Feng Wu 5.1 Introduction 185 5.2 Organic Reactions in DMC 185 References 197 6 Applications of Green Deep Eutectic Solvents (DESs) in Synthetic Transformations 199 Zhuan Zhang and Taoyuan Liang 6.1 Introduction 199 6.2 Cross-coupling Reactions in Deep Eutectic Solvents 201 6.2.1 C-C Bond Couplings 201 6.2.2 C-N Bond Couplings 210 6.2.3 C-O Bond Couplings 211 6.2.4 C-S Bond Couplings 212 6.3 Oxidation Reactions in Deep Eutectic Solvents 213 6.3.1 Metal-catalyzed Oxidation 213 6.3.2 Other Oxidative Processes 214 6.4 Reduction Reactions in Deep Eutectic Solvents 217 6.4.1 Metal-catalyzed Reduction 217 6.4.2 Other Catalytic Reduction 218 6.5 Cyclization Reactions in Deep Eutectic Solvents 219 6.5.1 Synthesis of Five-membered Ring 219 6.5.2 Synthesis of Six-membered Ring 220 6.6 Condensation Reactions in Deep Eutectic Solvents 221 6.6.1 DES as the Catalyst/Solvent System for Condensation 221 6.6.2 Other Catalytic System for Condensation 223 6.7 Multicomponent Reactions in Deep Eutectic Solvents 224 6.7.1 One-pot Three-component Reaction 224 6.7.2 One-pot Four-component Reaction 227 6.8 Other Organic Reactions in Deep Eutectic Solvents 228 6.8.1 Isomerization Reaction 228 6.8.2 Ring-opening Reaction 230 6.8.3 Esterification Reaction 230 6.9 Polymerization in DSEs 231 6.9.1 Anionic Polymerization of Alkenes 231 6.9.2 Glycolysis and Polyesterification 231 6.9.3 Oxidative Polymerization 232 6.9.4 Visible-light-driven RAFT Polymerization 232 6.10 Conclusion 233 References 233 7 Recent Achievements in Organic Reactions in Ionic Liquids 237 Jianxiao Li and Huanfeng Jiang 7.1 Introduction 237 7.2 Transition Metal-catalyzed Reactions 238 7.2.1 Palladium-catalyzed Cascade Cyclization Reaction 239 7.2.2 Carbonylation Reactions 248 7.2.3 Sonogashira Coupling Reactions 252 7.2.4 Suzuki Coupling Reactions 255 7.2.5 Copper-catalyzed Coupling Reactions 257 7.3 Outlook 259 List of Abbreviations 259 References 260 8 Recent Achievements in Organic Reactions in Ketones and Esters 263 Fan-Lin Zeng and Bing Yu 8.1 Introduction 263 8.2 Organic Reactions in Ketones 263 8.2.1 Organic Reactions in Cyrene 263 8.2.2 Organic Reactions in NBP 266 8.3 Organic Reactions in Esters 268 8.3.1 Organic Reactions in Organic Carbonates 268 8.3.2 Organic Reactions in γ-Valerolactone 270 8.3.3 Organic Reactions in Ethyl Lactate 273 8.4 Conclusion 275 References 275 9 Recent Achievements in Organic Reactions in Polyethylene Glycol 279 Zhiping Yin 9.1 Introduction 279 9.2 PEG in Pd-catalyzed Coupling Reactions 280 9.2.1 Pd-catalyzed C-C, C-Si Bonds Formation in PEG 280 9.2.2 Pd-catalyzed C-N, C-P Bond Formation in PEG 290 9.2.3 Pd-catalyzed C-O Bond Formation in PEG 291 9.2.4 Pd-catalyzed C-B Bond Formation in PEG 291 9.3 PEG in Cu-catalyzed Reactions 292 9.3.1 Cu-catalyzed C-C Bond Formation in PEG 292 9.3.2 Cu-catalyzed C-N Bond Formation in PEG 293 9.3.3 Cu-catalyzed C-O, C-S, and C-Se Bond Formation in PEG 296 9.4 PEG in Ni, Ru, and Pt-catalyzed Reactions 299 9.5 PEG in Organocatalysis Reactions 302 9.6 PEG in Multicomponent Reactions 304 9.7 PEG in Cyclization Reactions 306 9.7.1 Synthesis of Five-membered Ring Systems 306 9.7.2 Synthesis of Six and Seven-membered Ring Systems 308 9.8 Conclusion 309 Acknowledgments 310 References 310 10 Recent Advances in Organic Reactions Using Water as Solvent 317 Chang-Sheng Wang, Qiao Sun, Guowei Wang, Wei He, Zheng Fang, and Kai Guo 10.1 Introduction 317 10.2 Cross-Coupling Reactions 318 10.2.1 C-C Cross-Coupling 318 10.2.2 C-N Cross-Coupling 336 10.2.3 C-S Cross-Coupling 342 10.2.4 C-P Cross-Coupling 346 10.3 C-H Functionalization 347 10.3.1 C-C Bond Formation 347 10.3.2 C-N Bond Formation 364 10.3.3 C-O Bond Formation 367 10.3.4 C-X Bond Formation 369 10.3.5 C-H Annulation/Cyclization 370 10.4 C-C Activation 374 10.5 C-O Cleavage Reactions 376 10.6 Oxidative and Reductive Reactions 377 10.6.1 Electrochemical Oxidation 377 10.6.2 Reduction and Related Reactions 379 10.7 Substitution Reactions 381 10.7.1 Nucleophilic Substitution 381 10.7.2 Electrophilic Substitution 383 10.7.3 Radical Substitution 384 10.8 Addition Reactions 386 10.8.1 Nucleophilic Addition 386 10.8.2 Alkene/Alkyne Functionalization via Radical Addition 392 10.8.3 Alkene or Alkyne Functionalization via Radical-Free Addition 396 10.8.4 Cycloaddition Reactions 399 10.9 Cyclization or Annulation Reactions 403 10.9.1 Radical-Free Cyclization/Annulation 403 10.9.2 Radical Cyclization 406 10.10 Multicomponent Reaction (MCR) 410 10.11 Domino/Tandem/Cascade Reactions 417 10.11.1 Chemo-Domino/Tandem/Cascade Reactions 417 10.11.2 Chemoenzymatic Reactions 422 10.12 Rearrangement or Insertion Reactions 425 10.12.1 Rearrangement Reactions 425 10.12.2 Carbene Insertion/Transfer Reactions 429 10.13 Amide Condensation Reactions 431 10.14 Summary and Conclusions 435 Acknowledgments 435 References 435 Index 443mehr

Autor

Xiao-Feng Wu was born in China. He studied chemistry in Zhejiang Sci-Tech University (China), where he got his bachelor?s degree in science (2007). In the same year, he went to Rennes 1 University (France) and earned his master?s degree in 2009. Then he joined Matthias Beller?s group in Leibniz-Institute for Catalysis (Germany), where he completed his PhD in January 2012. Subsequently he started his independent research at LIKAT and ZSTU. In March 2017, Xiao-Feng defended his Habilitation successfully from Rennes 1 University (France). Xiao-Feng has authored >420 publications in international journals, meanwhile he is also the editor or author of >10 books.

Zhiping Yin received his bachelor's degree in pharmacy from The Medical School of Hunan Normal University in 2012 and got his master's degree in medicinal chemistry from The West China School of Pharmacy of Sichuan University in 2015 under the supervision of Professor Zhenlei Song. In July 2019, he received the Ph.D. degree in Chemistry from the University of Rostock, Germany, under the supervision of Prof. Xiao-feng Wu. In January 2020, he joined the School of Pharmacy of Jiangsu University to carry out his independent research work. His current research focuses on homogeneous catalysis involving gaseous molecule CO and SO2, organic electrochemical synthesis.


Liang-Nian He received his Ph.D. from Nankai University in 1996 under the guidance of academician Ru-Yu Chen. He then worked as a Chinese postdoctoral fellow with academician Ren-Xi Zhuo at Wuhan University. He worked as a Postdoctoral Research Associate at the National Institute of Advanced Science and Technology (Japan) from 1999 to 2003 before joining Nankai University in April of 2003. His research interests cover green chemistry, catalysis, and CO2 chemistry (CO2 activation and catalytic conversion into fuels/value-added chemicals; in situ transformation of CO2: combination of CO2 capture and subsequent conversion to chemicals and fuel-related products in a carbon neutral cycle), catalysis in green solvents and biomass conversion (castor-related energy), and green technology related to desulfurization.

Feng Wang received his BS degree at Zhengzhou University in 1999 and his PhD at Dalian Institute of Chemical Physics, Chinese Academy of Sciences in 2005. He joined the Organic Catalysis Group as an assistant professor in the same year. He later did postdoctoral research at the University of California-Berkeley and Hokkaido University-Catalysis Research Center. In 2009, he was promoted as a member of Hundred Talents program of the Chinese Academy of Sciences, and began his independent research as the leader of the Bioenergy Chemical Group. He now serves as the vice director of Dalian Institute of Chemical Physics, CAS and the director of the Biomass-Conversion and Bio-Energy division.
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