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Organic Chemistry
Kuiling Ding, Li-Xin Dai (Editors)
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Últimas novedades química orgánica
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This helpful, useful, practical book presents the most important achievements in organic chemistry over the past decade, summarizing such major developments as C-H activation, organocatalysis, and supramolecular chemistry. Each chapter contains two or three personal, hitherto unpublished, commentaries by leading experts on the topic. This reference work focuses on four main areas: the total synthesis of natural products and chemical biology; synthetic methodology; physical organic chemistry and chemistry relevant to meeting the urgent needs of humanity. The result is a complete and extremely useful source of a wide variety of information for graduate students, post-docs and researchers. |
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List of Contributors XXIII
Introduction XXXV
1 Diversity-Oriented Syntheses of Natural Products and Natural Product-Like Compounds 1 Ling-Min Xu, Yu-Fan Liang, Qin-Da Ye, and Zhen Yang
1.1 Introduction 1
1.2 Diversity-Oriented Synthesis (DOS) 2
1.3 Diverted Total Synthesis (DTS) 7
1.4 Function-Oriented Synthesis (FOS) 9
1.5 Target-Oriented Synthesis (TOS) 11
1.6 Conclusion and Perspectives 24
Acknowledgments 26
References 26
Commentary Part 28
Comment 1 28 Michael Foley
Comment 2 29 Scott A. Snyder
Comment 3 30 Da-Wei Ma
Authors’ Response to the Commentaries 31
References 31
2 Total Synthesis of Natural Products and the Synergy with Synthetic Methodology 33 Qian Wang and Jie-Ping Zhu
2.1 Introduction 33
2.2 Domino Process 36
2.3 Multicomponent Reactions 43
2.4 Oxidative Anion Coupling 52
2.5 Pattern Recognition 60
2.6 Conformation-Directed Cyclization 65
2.7 Conclusion and Perspectives 69
Acknowledgments 70
References 70
Commentary Part 72
Comment 1 72 Kyriacos C. Nicolaou
Comment 2 73 Henry N.C. Wong
Comment 3 75 Wei-Dong Li
References 77
3 Interplay Between the Chemical Space and the Biological Space 81 Ren-Xiao Wang
3.1 Chemical Biology: Historical and Philosophical Aspects 81
3.2 Preparation of Chemical Libraries 90
3.3 Screening Strategies 95
3.4 Target Elucidation and Validation 106
3.5 Conclusion and Perspectives 116
References 117
Commentary Part 121
Comment 1 121 Ke Ding
Comment 2 121 Li-He Zhang
Comment 3 122 Jun-Ying Yuan
Author’s Response to the Commentaries 122
References 123
4 Biosynthesis of Pharmaceutical Natural Products and Their Pathway Engineering 125 Michael J. Smanski, Xu-Dong Qu, Wen Liu, and Ben Shen
4.1 Introduction 125
4.2 Expanded Paradigms in Biosynthetic Logic 126
4.3 New Approaches to NP Biosynthesis Research 147
4.4 Better Understanding of the Scope and Diversity of NP Production 156
4.5 Future Perspectives 168
Acknowledgments 170
Abbreviations 171
References 171
Commentary Part 178
Comment 1 178 Yi Tang
Comment 2 178 Yi Yu and Zi-Xin Deng
Authors’ Response to the Commentaries 179
Response to Yi Tang 179
Response to Yi Yu and Zixin Deng 179
5 Carbohydrate Synthesis Towards Glycobiology 181 Biao Yu and Lai-Xi Wang
5.1 Introduction 181
5.2 Advances in Chemical Glycosylation 182
5.3 New Strategies in Oligosaccharide Assembly 189
5.4 Enzymatic and Chemoenzymatic Methods 193
5.5 Synthesis of Heparin and Heparan Sulfate Oligosaccharides 195
5.6 Synthesis of Homogeneous Glycoproteins 200
5.7 Synthesis of Carbohydrate-Containing Complex Natural Compounds 206
5.8 Conclusion and Perspectives 212
Acknowledgments 212
References 212
Commentary Part 218
Comment 1 218 Sam Danishefsky
Comment 2 218 David Crich
Authors’ Response to the Commentaries 219
References 219
6 Chemical Synthesis of Proteins 221 Lei Liu
6.1 Introduction 221
6.2 Brief History 222
6.3 Current Technology 227
6.4 Applications 236
6.5 Conclusion and Perspectives 242
References 242
Commentary Part 244
Comment 1 244 Sam Danishefsky
Comment 2 244 David Crich
References 245
7 CuAAC: the Quintessential Click Reaction 247 Valery V. Fokin
7.1 Introduction 247
7.2 Azide–Alkyne Cycloaddition: the Basics 249
7.3 CuAAC: Catalysts and Ligands 251
7.4 Mechanistic Aspects of the CuAAC 258
7.5 Reactions of 1-Iodoalkynes 264
7.6 Examples of Application of the CuAAC Reaction 266
7.7 Reactions of Sulfonyl Azides 269
7.8 Outlook/Perspective 273
Acknowledgments 273
References 273
Commentary Part 276
Comment 1 276 Krzysztof Matyjaszewski
References 276
8 Transition Metal-Catalyzed C–H Functionalization: Synthetically Enabling Reactions for Building Molecular Complexity 279 Keary M. Engle and Jin-Quan Yu
8.1 Introduction 279
8.2 Background and Early Work 281
8.3 First Functionalization: Challenges in Hydrocarbon Chemistry 293
8.4 Further Functionalization: C–H Bonds as Reaction Partners in Organic Synthesis 300
8.5 Catalytic C–H Functionalization via Metal Insertion 303
8.6 Other Emerging Metal-Catalyzed Further Functionalization Methods 311
8.7 Outlook and Conclusion 321
Acknowledgments 322
Abbreviations 322
References 323
Commentary Part 328
Comment 1 328 Huw M.L. Davies
Comment 2 329 Zhenfeng Xi
Comment 3 330 Shu-Li You
Comment 4 332 Zhang-Jie Shi
Authors’ Response to the Commentaries 333
References 333
9 An Overview of Recent Developments in Metal-Catalyzed Asymmetric Transformations 335 Christian A. Sandoval and Ryoji Noyori
9.1 Introduction 335
9.2 Asymmetric Carbon–Carbon Bond Formation 336
9.3 Asymmetric Reductions and Oxidations 348
9.4 Conclusion 353
References 353
Commentary Part 363
Comment 1 363 Qi-Lin Zhou
Comment 2 363 Andreas Pfaltz
Comment 3 365 Xue-Long Hou
Comment 4 365 Hisashi Yamamoto
References 366
10 The Proline-Catalyzed Mannich Reaction and the Advent of Enamine Catalysis 367 Benjamin List and Sai-Hu Liao
10.1 Introduction 367
10.2 The Proline-Catalyzed Mannich Reaction 367
10.3 Conclusion 374
References 374
Commentary Part 375
Comment 1 375 Seiji Shirakawa and Keiji Maruoka
Comment 2 377 The Early Status of Asymmetric Organocatalysis 377
Liu-Zhu Gong
Milestone in Asymmetric Organocatalysis 378
Enamine Catalysis 378
Iminium Catalysis 378
Domino Reactions by Amine Catalysis 378
Hydrogen Bonding Catalysis 378
Conclusion 379
Comment 3 379 Wen-Jing Xiao
References 382
11 Recent Topics in Cooperative Catalysis: Asymmetric Catalysis, Polymerization, Hydrogen Activation, and Water Splitting 385 Motomu Kanai
11.1 Introduction 385
11.2 Cooperative Catalysis in Asymmetric Reactions 387
11.3 Cooperative Catalysis in Alkene Polymerization 393
11.4 Cooperative Catalysis in Hydrogen Activation/Generation 394
11.5 Conclusion and Perspectives 398
References 398
Commentary Part 401
Comment 1 401 Takao Ikariya
Comment 2 402 Takashi Ooi
Comment 3 405 Kuiling Ding
Comment 4 409 David Milstein
Authors’ Response to the Commentaries 410
References 411
12 Flourishing Frontiers in Organofluorine Chemistry 413 G. K. Surya Prakash and Fang Wang
12.1 Introduction 413
12.2 Synthetic Approaches for the Introduction of Fluorine-Containing Functionalities and Related Chemistry 415
12.3 Conclusion and Perspectives 459
Acknowledgment 460
References 460
Commentary Part 470
Comment 1 470 David O’Hagan
Comment 2 471 Jinbo Hu
Comment 3 472 Kuiling Ding and Li-Xin Dai
Authors’ Response to the Commentaries 472
References 473
Addendum 473
13 Supramolecular Organic Chemistry: the Foldamer Approach 477 Zhan-Ting Li
13.1 Introduction 477
13.2 Foldamers: the Background 479
13.3 Molecular Recognition 480
13.4 Homoduplex 497
13.5 Organogels 499
13.6 Vesicles 501
13.7 Supramolecular Liquid Crystals 502
13.8 Macrocycles 503
13.9 Catalysis 510
13.10 Macromolecular Self-Assembly 514
13.11 Conclusion and Perspectives 516
Acknowledgments 517
References 517
Commentary Part 520
Comment 1 520 Peter J. Stang
Comment 2 521 Liang Zhao and Mei-Xiang Wang
Introduction 521
Macrocyclic Compounds 522
Cycloparaphenylenes 522
Pillar[n]arenes 524
Heteracalixaromatics 525
Noncovalent Interactions 527
Quadruple Hydrogen Bonding 527
Halogen Bonding 528
Anion–p Interaction 529
Perspectives 530
Acknowledgements 531
Comment 3 531 Chen-Ho Tung
Author’s Response to the Commentaries 532
Reply to Zhao and Wang’s Comments 532
Reply to Tung’s Comments 533
Reply to Stang’s Comments 533
References 533
14 Novel Catalysis for Alkene Polymerization Mediated by Post-Metallocenes: a Gateway to New Polyalkenes 537 Hiromu Kaneyoshi, Haruyuki Makio, and Terunori Fujita
14.1 Introduction 537
14.2 Late Transition Metal Complexes 538
14.3 Early Transition Metal Complexes 544
14.3.1 Phenoxyimine-Ligated Group 4 Metal Complexes 544
14.4 Conclusion and Perspectives 553
Acknowledgment 554
References 554
Commentary Part 555
Comment 1 555 Robert Grubbs
Comment 2 556 Jun Okuda
General 556
Early Work on Late Metals 556
Ligand Design Principles for Post-metallocenes 556
Comment 3 557 Eugene Y.-X. Chen
Authors’ Response to the Commentaries 559
References 559
15 Chem Is Try Computationally and Experimentally: How Will Computational Organic Chemistry Impact Organic Theories, Mechanisms, and Synthesis in the Twenty-First Century? 561 Zhi-Xiang Yu and Yong Liang
15.1 Introduction 561
15.2 Developing New Theories, Concepts, and Understandings for Organic Chemistry 561
15.3 Understanding Reaction Mechanisms 571
15.4 Computation-Guided Development of New Catalysts, New Reactions, and Synthesis Planning for Ideal Synthesis 583
15.5 Conclusion 595
Acknowledgments 597
References 597
Commentary Part 600
Comment 1 600 K. N. Houk
Comment 2 600 Yun-Dong Wu and Xin-Hao Zhang
References 601
16 Case Study of Mechanisms in Synthetic Reactions 603 Ai-Wen Lei and Li-Qun Jin
16.1 Introduction 603
16.2 Mechanistic Study of Coupling Reactions 604
16.3 Mechanistic Study of Aerobic Oxidation 627
16.4 Conclusion and Perspective 634
Acknowledgments 635
References 635
Commentary Part 638
Comment 1 638 Xin Mu, Guo-Sheng Liu, and Qi-Long Shen
Comment 2 640 Yoshinori Yamamoto
Authors’ Response to the Commentaries 640
References 640
17 Organic Materials and Chemistry for Bulk Heterojunction Solar Cells 643 Chun-Hui Duan, Fei Huang, and Yong Cao
17.1 Introduction 643
17.2 Molecular Design and Engineering of Donor Materials 645
17.3 Molecular Design and Engineering of Acceptor Materials 662
17.4 Conclusion and Outlook 671
Acknowledgments 671
References 671
Commentary Part 676
Comment 1 676 Niyazi Serdar Sariciftci
Comment 2 677 Yongfang Li
Comment 3 681 Guillermo C. Bazan
Comment 4 682 Xiong Gong
Authors’ Response to the Commentaries 682
References 682
18 Catalytic Utilization of Carbon Dioxide: Actual Status and Perspectives 685 Albert Boddien, Felix G¨artner, Christopher Federsel, Irene Piras, Henrik Junge, Ralf Jackstell, and Matthias Beller
18.1 Introduction 685
18.2 Catalytic Reductions of CO2 to Formic Acid and Methanol 686
18.3 CO2 as a C1-Building Block in C–C Coupling Reactions 702
18.4 Catalytic C–O Bond Formation Utilizing Carbon Dioxide 703
18.5 Current Industrial Processes Using CO2 710
18.6 Conclusion and Outlook 715
References 716
Commentary Part 722
Comment 1 722 Gábor Laurenczy
Comment 2 723 Min Shi
References 724
19 Synthetic Chemistry with an Eye on Future Sustainability 725 Guo-Jun Deng and Chao-Jun Li
19.1 Introduction 725
19.2 Cross-Dehydrogenative Coupling 729
19.3 Nucleophilic Addition of Terminal Alkynes in Water 741
19.4 Conclusion and Perspectives 749
Acknowledgments 750
References 750
Commentary Part 754
Comment 1 754 Roger A. Sheldon
Comment 2 756 Tak Hang Chan
References 758
20 Organic p-Conjugated Molecules for Organic Semiconductors and Photovoltaic Materials 759 De-Qing Zhang, Xiao-Wei Zhan, Zhao-Hui Wang, Jian Pei, Guan-Xin Zhang, and Dao-Ben Zhu
20.1 Introduction 759
20.2 Conjugated Molecules for p-Type Organic Semiconductors 760
20.3 Conjugated Molecules for n-Type Organic Semiconductors 766
20.4 Conjugated Molecules for Photovoltaic Materials 769
20.5 Conclusion and Outlook 773
References 774
Commentary Part 777
Comment 1 777 Seth R. Marder
Comment 2 777 Tien Yau Luh
Authors’ Response to the Commentaries 779
References 779
21 The Future of Organic Chemistry–an Essay 781 Ronald Breslow
21.1 Introduction 781
21.2 The Field of Organic Chemistry Will Broaden 781
21.3 Conclusion 789
Index 791
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