| Acknowledgements | p. xiv |
| Introduction | |
| Microporous Framework Solids: Definitions | p. 1 |
| Historical Development of the Subject | p. 1 |
| References | p. 6 |
| Families of Microporous Framework Solids | |
| Introduction | p. 8 |
| Aluminosilicate Zeolites and Silica Polymorphs | p. 11 |
| Structural Chemistry | p. 11 |
| Zeolite Framework Types | p. 13 |
| Substitutional Metallosilicates | p. 25 |
| Aliovalent Substitutions | p. 26 |
| Isovalent Substitutions (M[superscript 4+ left and right double arrow] Si[superscript 4+]) | p. 27 |
| Metallophosphate Zeotypes and Related Materials | p. 28 |
| Aluminophosphates (AlPO[subscript 4]s) | p. 28 |
| Substituted AlPO[subscript 4]s | p. 30 |
| Mixed Coordination Inorganic Frameworks | p. 33 |
| Metallosilicates | p. 33 |
| Metallophosphates | p. 39 |
| Germanates | p. 40 |
| Microporous Metal Oxides-Octahedral Molecular Sieves | p. 41 |
| Non-oxide Microporous Solids | p. 43 |
| Microporous Organic-Inorganic Hybrids | p. 44 |
| Organically-lined Inorganic Frameworks | p. 44 |
| Porous Metal Organic Frameworks | p. 46 |
| Mesoporous Solids | p. 60 |
| Hypothetical Networks | p. 66 |
| Hypothetical Zeolites | p. 67 |
| Nets and MOFs | p. 68 |
| Summary | p. 71 |
| References | p. 71 |
| Structure Determination: Experimental Techniques | |
| Introduction | p. 79 |
| Diffraction-based Methods | p. 80 |
| Single Crystal Diffraction | p. 81 |
| X-ray and Neutron Powder Diffraction | p. 83 |
| Electron Diffraction and Transmission Electron Microscopy | p. 95 |
| Structural Studies of Mesoporous Solids | p. 99 |
| 3D TEM-Electron Tomography | p. 103 |
| Scanning Electron Microscopy and Scanning Probe Microscopy | p. 106 |
| Spectroscopic Methods in Structural Studies | p. 108 |
| Solid State NMR Spectroscopy | p. 108 |
| X-ray Absorption Spectroscopy (XANES and EXAFS) | p. 131 |
| Vibrational Spectroscopy | p. 136 |
| Other Spectroscopies: UV-visible, Electron Spin Resonance | p. 138 |
| Summary | p. 139 |
| References | p. 141 |
| Computer Modelling | |
| Introduction and Definitions | p. 148 |
| Structure Simulation using Interatomic Potentials: Molecular Mechanics | p. 149 |
| Structural Simulation using Pair Potentials: Energy Calculation | p. 151 |
| Energy Minimisation and Simulated Annealing Techniques | p. 153 |
| Application of Monte Carlo Methods to Structure Simulation | p. 154 |
| Application of Pair-potential Methods to the Study of Surfaces | p. 154 |
| Structure Simulation using Quantum Mechanical Methods | p. 156 |
| Quantum Mechanical Methods | p. 156 |
| Density Functional Theory | p. 157 |
| Applications of Modelling to Structure Simulation | p. 158 |
| Structural Studies through Energy Minimisation | p. 158 |
| Bonding in Microporous Solids: Substitutional Behaviour | p. 159 |
| Organic and Inorganic Cation Sites: Monte Carlo/Simulated Annealing Approaches | p. 161 |
| Structure Simulation as an Aid to Structure Solution: Hypothetical Structures | p. 161 |
| Simulating Physisorption in Porous Solids | p. 164 |
| Monte Carlo Methods: Grand Canonical Monte Carlo (GCMC) | p. 166 |
| Configurational Bias GCMC Methods | p. 167 |
| Molecular Dynamics | p. 169 |
| Transition State Theory and Related Methods | p. 170 |
| Modelling Chemical Bonding and Reactivity | p. 172 |
| Nucleation and Crystal Growth | p. 172 |
| Chemisorption | p. 172 |
| Catalytic Activity | p. 174 |
| Summary | p. 175 |
| References | p. 176 |
| Synthesis | |
| Introduction | p. 180 |
| Principles of Hydrothermal Synthesis | p. 181 |
| Synthesis of Zeolites | p. 185 |
| Gel Formation | p. 185 |
| Crystallisation Curves and Sequences | p. 190 |
| The induction Period and Nucleation | p. 190 |
| Crystal Growth | p. 193 |
| Issues in Zeolite Synthesis | p. 197 |
| Role of the Structure-directing Agent: Designed 'Templates' | p. 197 |
| The Fluoride Route | p. 201 |
| Incorporation of Aluminium and Other Heteroatoms | p. 202 |
| Modifying Crystallite Size: Nano- and Giant Zeolite Crystals | p. 205 |
| Synthesis of Other Microporous Solids | p. 207 |
| Aluminium and Other Metal Phosphates | p. 207 |
| Metal-organic Frameworks | p. 211 |
| High-throughput Synthesis | p. 212 |
| Synthesis of Ordered Mesoporous Solids | p. 212 |
| A General Synthesis Pathway to Mesoporous Solids | p. 212 |
| Mechanisms of Silicate Mesophase Formation from Aqueous Solution | p. 215 |
| True Liquid Crystal Templating and Evaporation-induced Mesostructure Formation: Non-silica Mesoporous Solids | p. 218 |
| Summary | p. 218 |
| References | p. 220 |
| The Chemistry of Microporous Framework Solids | |
| Introduction | p. 226 |
| Stability and Post-synthetic Modification | p. 226 |
| Thermal Stability of the Framework | p. 226 |
| Chemical Conversions during Calcination | p. 229 |
| Dealumination and the Preparation of 'Ultrastable' Zeolite Y | p. 231 |
| Stability in Aqueous Solution | p. 235 |
| Post-synthetic Modification: Metallation and Pore-size Modification | p. 236 |
| Cation Exchange | p. 236 |
| Cation Exchange in Aqueous Solution | p. 236 |
| Solid State Ion Exchange and Intra-zeolite Cation Migration | p. 242 |
| Inclusion Chemistry | p. 243 |
| Alkali Metals in Zeolites | p. 244 |
| Sulfide Chromophores: The Ultramarine Family | p. 246 |
| Metal Chalcogenides and Other Inclusion Compounds | p. 246 |
| Inclusion of Complexes by MOCVD | p. 246 |
| Reduction and Oxidation Chemistry | p. 247 |
| Reduction of Extra-framework Transition Metal Cations | p. 247 |
| Redox Behaviour of Framework Transition Metal Cations | p. 248 |
| Intra-zeolitic Chemistry | p. 249 |
| Isolated Molecules and Arrays of Molecules | p. 249 |
| Chemistry of Mesoporous Solids | p. 251 |
| Hydrothermal Stability and Post-synthetic Functionalisation | p. 251 |
| Summary | p. 252 |
| References | p. 253 |
| Adsorption and Diffusion | |
| Introduction and Definitions | p. 257 |
| Introduction | p. 257 |
| Definitions | p. 258 |
| Theory and Methods for the Study of Adsorption | p. 264 |
| Adsorption Isotherms | p. 264 |
| Thermodynamics: Microcalorimetry and Thermal Desorption | p. 270 |
| Molecular Motion of Adsorbates | p. 273 |
| Adsorption Sites and Adsorbate-solid Complexes: Vibrational Spectroscopy, NMR and Diffraction | p. 276 |
| Computer Simulation of Adsorption: General Lessons | p. 279 |
| Adsorption Sites and Interactions with Adsorbates | p. 280 |
| Neutral Frameworks | p. 280 |
| Extra-framework Cations | p. 286 |
| Structural Hydroxyls | p. 290 |
| Framework Lewis Acid Sites | p. 291 |
| Basic Sites | p. 293 |
| Metal-Organic Frameworks | p. 294 |
| Diffusion | p. 295 |
| Introduction: Self-diffusion and Transport Diffusion | p. 295 |
| Experimental Methods and Simulations | p. 297 |
| Examples | p. 299 |
| Applications of Adsorption | p. 300 |
| Drying and Impurity Removal | p. 301 |
| Air Separation | p. 302 |
| Hydrocarbon Adsorption and Separation | p. 303 |
| True Molecular Sieving for Small Molecules | p. 304 |
| Summary | p. 305 |
| References | p. 306 |
| Microporous Solid Acid Catalysts and their Applications | |
| Introduction | p. 312 |
| The Chemistry of Acid Catalysis | p. 313 |
| General Features of Solid Acids | p. 317 |
| Acid Site Type, Concentration and Strength | p. 317 |
| Microporous Solids as Acid Catalysts | p. 319 |
| The Competitors: Other Classes of Solid Acids | p. 321 |
| Measurement of Acid Site Concentration and Strength in Microporous Solids | p. 322 |
| Direct Observation of Bronsted Acid Sites | p. 323 |
| Interaction of Bronsted Acid Sites with Probe Molecules | p. 324 |
| Acid Catalysis: Activity Measurement by Catalytic Test Reaction | p. 333 |
| Mechanisms of Acid Catalysed Reactions from in situ NMR and Quantum Mechanical Calculations | p. 335 |
| Trends in Performance of Microporous Solid Acids | p. 338 |
| The Role of Chemical Composition | p. 339 |
| The Role of Local Framework Structure | p. 340 |
| The Role of Lewis Acidity | p. 340 |
| The Role of Pore Structure: The Origin of Shape Selectivity | p. 341 |
| Catalytic Test Reactions: Information on Pore Geometry | p. 344 |
| Reactions over Microporous Solid Acids | p. 347 |
| Acid Catalysis with Reactants that Contain Heteroatoms | p. 349 |
| Hydrocarbon Conversions | p. 356 |
| Bifunctional Catalysis | p. 364 |
| Limitations of Microporous Solid Acid Catalysts | p. 365 |
| Summary | p. 366 |
| References | p. 367 |
| Further Catalytic Applications of Microporous Solids | |
| Introduction | p. 372 |
| Framework Lewis Acids as Selective Oxidation Catalysts | p. 373 |
| Selective Oxidation over Titanosilicates | p. 373 |
| Sn-Beta: a Versatile Catalyst for Baeyer-Villiger Oxidations and Meerwein-Ponndorf-Verley-Oppenauer Conversions | p. 381 |
| Selective Oxidations over AlPO[subscript 4]s Containing Redox-active Framework Cations | p. 383 |
| Catalysis over Extra-framework Metal Species | p. 387 |
| Transformation of Light Hydrocarbons into Aromatics | p. 388 |
| Catalytic Removal of NO[subscript x] Species from Auto-exhaust and Power Plant Emissions | p. 389 |
| Selective Oxidation with N[subscript 2]O over Fe-zeolites | p. 391 |
| Palladium-containing Zeolites for C-C Bond Formation | p. 392 |
| Base Catalysis | p. 392 |
| Supported Metal Complexes in Porous Solids | p. 395 |
| Ship-in-a-bottle Type Catalysts in Zeolitic Solids | p. 395 |
| Summary | p. 399 |
| References | p. 399 |
| Advanced Applications and Current Trends | |
| Introduction | p. 403 |
| Fabricating Porous Solids for Developing Applications | p. 404 |
| Zeolite Membranes | p. 404 |
| Thin films and Low Dielectric Constant Materials | p. 407 |
| Hierarchical Porosity | p. 408 |
| Using Ordered Porous Solids as Hosts in Functional Materials | p. 410 |
| Applications in Medicine: MRI Contrast Agents and Drug Delivery Agents | p. 410 |
| Optical and Electronic Properties | p. 411 |
| Gas Storage and Polymerisation in Responsive Metal-organic Frameworks | p. 412 |
| Summary and Final Remarks | p. 414 |
| References | p. 415 |
| Subject Index | p. 417 |
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