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Catalytic Asymmetric Synthesis. Группа авторов
Читать онлайн.Название Catalytic Asymmetric Synthesis
Год выпуска 0
isbn 9781119736417
Автор произведения Группа авторов
Жанр Химия
Издательство John Wiley & Sons Limited
21 Chapter 21Scheme 21.1 Enantioselective polymerization of various racemic monosubstitut...Scheme 21.2 Monomers and ligands used in asymmetric anionic polymerization o...Scheme 21.3 Divinyl monomer and catalysts used in enantioselective cyclopoly...Scheme 21.4 Stereospecific polymerization of cyclic olefins, and employed li...Scheme 21.5 Chiral ligands used in asymmetric alternating copolymerization o...Scheme 21.6 Enantioselective resolution homopolymerization of propylene oxid...Scheme 21.7 Catalysts used in asymmetric copolymerization of meso‐epox...Scheme 21.8 Intramolecular bimetallic mechanism for enantioselective polymer...Scheme 21.9 Asymmetric copolymerization of cyclohexane epoxide with COS medi...Scheme 21.10 Various catalysts involved in enantioselective polymerization o...Scheme 21.11 Kinetic resolution polymerization of racemic eight‐membered cyc...Scheme 21.12 Asymmetric copolymerization of various meso‐epoxides with cycli...Scheme 21.13 Enantioselective resolution copolymerization of racemic termina...Scheme 21.14 Asymmetric condensation polymerization.Scheme 21.15 Asymmetric oxidative‐coupling polymerization of 2,3‐dihudroxyna...
22 Chapter 22Figure 22.1. Classification of flow reactions in fine organic synthesis.Figure 22.2. Batch method and continuous‐flow method – from the viewpoint of...Figure 22.3. Type IV continuous‐flow enantioselective 1,4‐addition with poly...Figure 22.4 Type III continuous‐flow enantioselective 1,4‐addition and catal...Figure 22.5 Sequential continuous‐flow synthesis of the baclofen precursor....Figure 22.6. Mesoporous silica/Ni–diamine composite for continuous‐flow synt...Figure 22.7. Polymer‐bound nickel–diamine catalyst for continuous‐flow 1,4‐a...Figure 22.8. Immobilized organocatalytic continuous‐flow 1,4‐addition reacti...Figure 22.9. Continuous‐flow enantioselective 1,4‐addition reaction of aldeh...Figure 22.10. Continuous‐flow enantioselective 1,4‐addition reaction of alde...Figure 22.11. Hydroxyquinone 1,4‐addition to nitrostyrene.Figure 22.12. Continuous‐flow 1,4‐addition of ketone to nitroolefin.Figure 22.13. Quinine/benzoic acid bifunctional catalysis for enantioselecti...Figure 22.14. CPA‐containing MOF‐catalyzed enantioselective 1,4‐addition of ...Figure 22.15. Amphiphilic resin‐supported chiral diene Rh complex.Figure 22.16. Ligand–Rh/Ag nanoparticle Co‐immobilization system for continu...Figure 22.17. Asymmetric Robinson annulation.Figure 22.18. Continuous‐flow Aldol reaction with a homogeneous catalyst‐pac...Figure 22.19. Asymmetric organocatalytic Aldol reaction (Type III) in hydrop...Figure 22.20. Silica‐immobilized H8‐BINOL as a catalyst for organo‐titanium ...Figure 22.21. Polystyrene‐supported cinchona alkaloid‐derived thiourea catal...Figure 22.22. Porous carbon nanosheet/polymer hybrid‐supported chiral squara...Figure 22.23. Continuous‐flow enantioselective Henry reaction with Nd/Na het...Figure 22.24. Continuous‐flow enantioselective Strecker‐type reaction with c...Figure 22.25. Continuous‐flow hydrocyanation reaction with immobilized enzym...Figure 22.26. Type IV continuous‐flow enantioselective Mannich reaction inte...Figure 22.27. Continuous‐flow asymmetric allylboration with polymer‐supporte...Figure 22.28. Chiral NHC catalysis under continuous‐flow conditions.Figure 22.29. Continuous‐flow enantioselective Diels–Alder reaction using im...Figure 22.30. Optimization of Type III continuous‐flow reaction with the ass...Figure 22.31. Homochiral cage catalyst for continuous‐flow enantioselective ...Figure 22.32. Anchor effects in organocatalytic enantioselective cyclopropan...Figure 22.33. Continuous‐flow enantioselective C–H insertion reaction with s...Figure 22.34. Type III continuous‐flow asymmetric hydroformylation.Figure 22.35. Heterogeneous Rh catalyst immobilized on carbon by π–π interac...Figure 22.36. Continuous‐flow enantioselective α‐amination of oxindole.Figure 22.37. Photopolymerized chiral monolithic chip reactor for continuous...Figure 22.38. Type IV continuous‐flow enantioselective electrophilic fluorin...Figure 22.39. Type III continuous‐flow enantioselective electrophilic fluori...Figure 22.40. Type III continuous‐flow enantioselective photooxygenation of ...Figure 22.41. Continuous‐flow enantioselective electrochemical process.Figure 22.42. Type III continuous‐flow enantioselective sulfoxidation.Figure 22.43. Continuous‐flow kinetic resolution of racemic alcohol.Figure 22.44. Supported isothiourea catalyst in continuous‐flow kinetic reso...Figure 22.45. Continuous‐flow desymmetrization with immobilized chiral SPINO...Figure 22.46. Type III Corey–Bakshi–Shibata reductions in a microreactor sys...Figure 22.47. Type III organocatalytic enantioselective reductions of nitroe...Figure 22.48. Type III continuous‐flow asymmetric transfer hydrogenation inv...Figure 22.49. Continuous‐flow enantioselective MPV‐type reduction with suppo...Figure 22.50. Enantioselective hydrogenation of imines using supported Ir/no...Figure 22.51. Continuous‐flow organocatalytic enantioselective hydrosilylati...Figure 22.52. Supported rhodium‐catalyzed Type IV continuous‐flow enantiosel...Figure 22.53. Supported rhodium‐catalyzed Type IV continuous‐flow enantiosel...Figure 22.54. Modified Augustine approach for continuous‐flow enantioselecti...Figure 22.55. Assembling catalytic functions into single heterogeneous mater...
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