Series Preface |
Preface to Volume 4 |
Abbreviations |
An Overview of Zeolite, Zeotype and Mesoporous Solids Chemistry: Design, Synthesis and Catalytic Properties / Thomas Maschmeyer ; Leon van de Water1: |
Zeolites, zeotypes and mesoporous solids: synthetic aspects / 1.1: |
Introduction / 1.1.1: |
Synthetic aspects: template theory for zeolite synthesis / 1.1.2: |
Synthetic aspects: template theory for mesoporous oxides synthesis / 1.1.3: |
Design of extra-large pore zeolites and other micro- and mesoporous catalysts / 1.2: |
Extra-large pore zeolites / 1.2.1: |
Hierarchical pore architectures: combining micro- and mesoporosity / 1.2.3: |
Potential of post-synthesis functionalized micro- and mesoporous solids as catalysts for fine chemical synthesis / 1.3: |
Covalent functionalization / 1.3.1: |
Noncovalent immobilization approaches / 1.3.3: |
Single-site catalysts inspired by natural systems / 1.3.4: |
References |
Problems and Pitfalls in the Applications of Zeolites and other Microporous and Mesoporous Solids to Catalytic Fine Chemical Synthesis / Michel Guisnet ; Matteo Guidotti2: |
Zeolite catalysed organic reactions / 2.1: |
Fundamental and practical differences with homogeneous reactions / 2.2.1: |
Batch mode catalysis / 2.2.2: |
Continuous flow mode catalysis / 2.2.3: |
Competition for adsorption: influence on reaction rate, stability and selectivity / 2.2.4: |
Catalyst deactivation / 2.2.5: |
General conclusions / 2.3: |
Aromatic Acetylation / 3: |
Aromatic acetylation / 3.1: |
Acetylation with Acetic Anhydride / 3.1.1: |
Acetylation with Acetic Acid / 3.1.2: |
Procedures and protocols / 3.2: |
Selective synthesis of acetophenones in batch reactors through acetylation with acetic anhydride / 3.2.1: |
Selective synthesis of acetophenones in fixed bed reactors through acetylation with acetic anhydride / 3.2.2: |
Aromatic Benzoylation / Patrick Geneste ; Annie Finiels4: |
Aromatic benzoylation / 4.1: |
Effect of the zeolite / 4.1.1: |
Effect of the acylating agent / 4.1.2: |
Effect of the solvent / 4.1.3: |
Benzoylation of phenol and the Fries rearrangement / 4.1.4: |
Kinetic law / 4.1.5: |
Substituent effect / 4.1.6: |
Experimental / 4.1.7: |
Acylation of anisole over mesoporous aluminosilicates / 4.2: |
Nitration of Aromatic Compounds / Avelino Corma ; Sara Iborra5: |
Reaction mechanism / 5.1: |
Nitration of aromatic compounds using zeolites as catalysts / 5.3: |
Nitration in liquid phase / 5.3.1: |
Vapour phase nitration / 5.3.2: |
Conclusions / 5.4: |
Oligomerization of Alkenes / 6: |
Reaction mechanisms / 6.1: |
Acid zeolites as catalysts for oligomerization of alkenes / 6.3: |
Medium pore zeolites: influence of crystal size and acid site density / 6.3.1: |
Use of large pore zeolites / 6.3.2: |
Catalytic membranes for olefin oligomerization / 6.3.3: |
Mesoporous alominosilicates as oligomerization catalysts / 6.4: |
Nickel supported aluminosilicates as catalysts / 6.5: |
Microporous and Mesoporous Catalysts for the Transformation of Carbohydrates / Claude Moreau7: |
Hydrolysis of sucrose in the presence of H-form zeolites / 7.1: |
Hydrolysis of fructose and glucose precursors / 7.3: |
Isomerization of glucose into fructose / 7.4: |
Dehydration of fructose and fructose-precursors / 7.5: |
Dehydration of xylose / 7.6: |
Synthesis of alkyl-D-glucosides / 7.7: |
Synthesis of butyl-D-glucosides / 7.7.1: |
Synthesis of long-chain alkyl-D-glucosides / 7.7.2: |
Synthesis of alkyl-D-fructosides / 7.8: |
Hydrogenation of glucose / 7.9: |
Oxidation of glucose / 7.10: |
One-pot Reactions on Bifunctional Catalysts / 7.11: |
Examples / 8.1: |
One-pot transformations involving successive hydrogenation and acid-base steps / 8.2.1: |
One-pot transformations involving successive oxidation and acid-base steps / 8.2.2: |
Base-type Catalysts / Didier Tichit ; Daniel Brunel9: |
Characterization of solid bases / 9.1: |
Test reactions / 9.2.1: |
Probe molecules combined with spectroscopic methods / 9.2.2: |
Solid base catalysts / 9.3: |
Alkaline earth metal oxides / 9.3.1: |
Catalysis on alkaline earth metal oxides / 9.3.2: |
Hydrotalcites and related compounds / 9.3.3: |
Organic base-supported catalysts / 9.3.4: |
Hybrid Oxidation Catalysts from Immobilized Complexes on Inorganic Microporous Supports / Dirk De Vos ; Ive Hermans ; Ben Sels ; Pierre Jacobs9.4: |
Introduction and scope / 10.1: |
Oxygenation potential of heme-type complexes in zeolite / 10.2: |
Metallo-phthallocyanines encapsulated in the cages of faujasite-type zeolites / 10.2.1: |
Oxygenation potential of metallo-phthallocyanines encapsulated in the mesopores of VPI-5 AIPO[subscript 4] / 10.2.2: |
Oxygenation potential of zeolite encapsulated metallo-porphyrins / 10.2.3: |
Oxygenation potential of zeolite encapsulated nonheme complexes / 10.3: |
Immobilization of N,N[prime]-bidentate complexes in zeolite Y / 10.3.1: |
Ligation of zeolite exchanged transition ions with bidentate aza ligands / 10.3.2: |
Ligation of zeolite exchanged transition ions with tri- and tetra-aza(cyclo)alkane ligands / 10.3.3: |
Ligation of zeolite exchanged transition ions with Schiff base-type ligands / 10.3.4: |
Zeolite effects with N,N[prime]-bis(2-pyridinecarboxamide) complexes of Mn and Fe in zeolite Y / 10.3.5: |
Zeolite encapsulated chiral oxidation catalysts / 10.3.6: |
Acknowledgements / 10.4: |
Subject Index |