Supramolecular chemistry

A one-stop, comprehensive, and thoroughly updated resource for students, professors, and researchers alike Thoroughly revised and updated, the Third Edition of Supramolecular Chemistry delivers a comprehensive and integrated approach to this rapidly evolving and quickly expanding field. Distinguished professors and authors Jonathan Steed and Jerry Atwood provide readers with a broad and exhaustive resource that assumes little in the way of prior knowledge of supramolecular chemistry. Extensive new content on cutting edge research throughout the field including molecular machines and the mechanical bond, mechanochemistry, halogen bonding, and crystal nucleation accompanies full-color imagery and study problems designed to help students understand and apply the principles introduced within the book. Additional material is provided in the supplementary online resources, including solutions to the student exercises and PowerPoint slides of the figures in the book. Supramolecular Chemistry, Third Edition also includes: The latest research and developments reported over the last decade A unique "key references" system that highlights crucial reviews and primary literature A description of key experimental techniques included in accessible "boxes" for the non-expert Exercises and problems for students, complete with online solutions Full-color illustrations and imagery designed to facilitate learning and retention of the key concepts and state-of-the art of the field Perfect for undergraduate and postgraduate students taking courses on supramolecular chemistry, the Third Edition of Supramolecular Chemistry also belongs on the bookshelves of all researchers in this, and any closely related, fields. Academics, in particular postdoctoral students and professors, will benefit significantly from this text.

About the Authors xvii Preface to the Third Edition xix Acknowledgements xxi About the Front Cover xxiii About the Companion Website xxiii Chapter 1 Concepts 1 1.1 Definition and Development of Supramolecular Chemistry 1 1.2 Classification of Supermolecule Formation 4 1.3 Receptors, Coordination, and the Lock and Key Analogy 11 1.4 Binding Constants 14 1.5 Cooperativity, Multivalency, and the Chelate Effect 29 1.6 Preorganisation and Complementarity 36 1.7 Thermodynamic and Kinetic Selectivity, and Discrimination 38 1.8 Nature of Supramolecular Interactions 40 1.9 Solvation Effects 57 1.10 Supramolecular Concepts and Design 61 1.11 Practical Applications of Supramolecular Chemistry 73 Chapter 2 The Supramolecular Chemistry of Life 83 2.1 Biological Inspiration for Supramolecular Chemistry 83 2.2 Alkali Metal Cations in Biochemistry 84 2.3 Porphyrins and Tetrapyrrole Macrocycles 96 2.4 Supramolecular Features of Plant Photosynthesis 99 2.5 Uptake and Transport of Oxygen by Haemoglobin 106 2.6 Enzymes and Coenzymes 111 2.7 Signalling: Neurotransmitters, Hormones, and Pheromones 117 2.8 DNA and the Genetic Code 121 2.9 Biochemical Self-Assembly 134 2.10 Biomineralisation 137 2.11 Emergence of Life 141 Chapter 3 Cation-Binding Hosts 147 3.1 Introduction to Coordination Chemistry 147 3.2 Podands 153 3.3 The Crown and Lariat Ethers 158 3.4 The Cryptands 163 3.5 The Spherands 165 3.6 Nomenclature of Cation-Binding Macrocycles 167 3.7 Selectivity of Cation Complexation 169 3.8 Solution Behaviour and Applications of Crowns and Cryptands 184 3.9 Macrocycle Synthesis: The Template Effect and High Dilution 189 3.10 Soft Ligands for Soft Metal Ions 196 3.11 Proton Binding: The Simplest Cation 212 3.12 Complexation of Organic Cations 217 3.13 Alkalides and Electrides 231 3.14 The Calixarenes 234 3.15 Carbon Donor and -acid Ligands 244 3.16 The Siderophores 250 Chapter 4 Anion Binding 265 4.1 Introduction 265 4.2 Biological Anion Receptors 268 4.3 Concepts in Anion Host Design 274 4.4 Cationic Receptors 283 4.5 Neutral Receptors 300 4.6 Boron Based Receptors and Lewis Acid Chelates 319 4.7 Metal-Containing Receptors 323 4.8 Anion-Binding Helices 333 4.9 Anion Transport 336 Chapter 5 Ion-Pair Receptors 351 5.1 Simultaneous Anion and Cation Binding 351 5.2 Labile Coordination Complexes and Cages as Anion Hosts 367 5.3 Receptors for Zwitterions 375 Chapter 6 Molecular Guests in Solution 381 6.1 Molecular Hosts and Molecular Guests 381 6.2 Intrinsic Curvature: Guest Binding by Cavitands 384 6.3 Cyclodextrins 401 6.4 Molecular Tweezers, Clips and Clefts 411 6.5 Cyclophane Hosts 415 6.6 Constructing a Solution Host from Clathrate-Forming Building Blocks: The Cryptophanes 440 6.7 Covalent Cages: Carcerands and Hemicarcerands 450 6.8 Coordination Cages 460 6.9 Halogen-Bonded Complexes 461 Chapter 7 Solid-State Inclusion Compounds 469 7.1 Nomenclature and Thermochemical Aspects 469 7.2 Porosity and Gas Sorption 473 7.3 Clathrate Hydrates 479 7.4 Urea and Thiourea Clathrates 486 7.5 Channel Clathrates 492 7.6 Polarity Formation 497 7.7 Hydroquinone, Phenol, Dianin's Compound, and the Hexahost Strategy 501 7.8 Macrocyclic Clathrates 504 7.9 Covalent Cages 522 7.10 Gas Sorption by Coordination Complex Hosts 527 Chapter 8 Crystal Engineering 537 8.1 Concepts 537 8.2 Crystal Nucleation and Growth 550 8.3 Understanding Crystal Structures 574 8.4 The Cambridge Structural Database 589 8.5 Polymorphism 592 8.6 Co-crystals 603 8.7 Solid State Transformations 617 8.8 Crystal Structure Prediction 624 8.9 Common and Exotic Supramolecular Synthons 629 8.10 Halogen Bonding 640 8.11 Bending and Jumping Crystals 642 Chapter 9 Network Solids 655 9.1 What are Network Solids? 655 9.2 Zeolites 662 9.3 Layered Solids and Intercalates 670 9.4 In the Beginning: Hoffman Inclusion Compounds and Werner Clathrates 676 9.5 Coordination Polymers 679 9.6 Porous Metal-Organic Frameworks 696 9.7 Covalent Organic Frameworks 716 Chapter 10 Self-Assembly 727 10.1 Introduction 727 10.2 Proteins and Foldamers: Single-Molecule Self-Assembly 733 10.3 Biochemical Self-Assembly 736 10.4 Self-Assembly in Synthetic Systems: Kinetic and Thermodynamic Considerations 739 10.5 Helicates and Helical Assemblies 755 10.6 Self-Assembling Coordination Compounds 768 10.7 Self-Assembly of Closed Complexes by Hydrogen Bonding 793 10.8 Templated Assembly of Porphyrin Arrays 805 10.9 Programmed Assembly with Biomolecules 807 Chapter 11 The Mechanical Bond 815 11.1 Scope and Importance of Mechanical Bonding and Mechanostereochemistry 815 11.2 Catenanes and Rotaxanes 816 11.3 Molecular Knots 846 11.4 Borromean Rings and Multiply Interlocked Catenanes 857 11.5 Interpenetrated Cages 860 11.6 An Unusual Thring 861 Chapter 12 Molecular Devices and Machines 867 12.1 Introduction 867 12.2 Supramolecular Photochemical Devices 870 12.3 Information and Signals: Semiochemistry and Sensing 890 12.4 Molecule-Based Electronics 909 12.5 Molecular Analogues of Mechanical Machines 923 Chapter 13 Biological Mimics and Supramolecular Catalysis 945 13.1 Introduction 945 13.2 Cyclodextrins as Enzyme Mimics 948 13.3 Corands as ATPASE Mimics 953 13.4 Cation-Binding Hosts as Transacylase Mimics 955 13.5 Metallobiosites 958 13.6 Enzyme Mimetic Materials 977 13.7 Ion Channel Mimics 978 13.8 Supramolecular Catalysis 985 Chapter 14 Interfaces and Liquid Assemblies 1003 14.1 Order in Liquids 1003 14.2 Surfactants and Interfacial Ordering 1005 14.3 Liquid Crystals 1018 14.4 Polyamorphous Liquids 1030 14.5 Ionic Liquids and Deep Eutectic Solvents 1032 14.6 Liquid Clathrates 1033 14.7 Porous Liquids 1036 Chapter 15 Supramolecular Materials 1043 15.1 Introduction 1043 15.2 Dendrimers 1044 15.3 Fractal Assemblies 1062 15.4 Covalent Polymers with Supramolecular Properties 1063 15.5 Self-Assembled Supramolecular Polymers 1068 15.6 Mechanically Interlocked Materials 1077 15.7 Supramolecular Gels 1084 15.8 Polymeric Liquid Crystals 1091 15.9 Biological Self-Assembled Materials 1093 Chapter 16 Dynamic Covalent Bonding and Complex Systems 1101 16.1 Chemistry Out of Equilibrium 1101 16.2 Dynamic Combinatorial Libraries 1102 16.3 Self-Replication 1106 16.4 Shapeshifting Molecules 1111 16.5 Dissipative Self-Assembly 1113 Chapter 17 Nanochemistry 1119 17.1 When Is Nano Really Nano? 1119 17.2 Nanotechnology: The 'Top-Down' and 'Bottom-Up' Approaches 1120 17.3 Templated and Biomimetic Morphosynthesis 1121 17.4 Nanoscale Photonics 1124 17.5 Microfabrication, Nanofabrication and Soft Lithography 1126 17.6 Assembly and Manipulation on the Nanoscale 1132 17.7 Nanoparticles 1144 17.8 Endohedral Fullerenes, Nanotubes and Graphene 1152 Index 1165