Main Group Metal Coordination Polymers: Structures and Nanostructures

Coordination polymer is a general term used to indicate an infinite array composed of metal ions which are bridged by certain ligands among them. This incorporates a wide range of architectures including simple one–dimensional chains with small ligands to large mesoporous frameworks. Generally, the formation process proceeds automatically and, therefore, is called a self–assembly process. In general, the type and topology of the product generated from the self–assembly of inorganic metal nodes and organic spacers depend on the functionality of the ligand and valences and the geometric needs of the metal ions used. In this book the authors explain main group metal coordination polymer in bulk and nano size with some of their application, synthesis method and etc, The properties of these efficient materials are described at length including magnetism (long–range ordering, spin crossover), porosity (gas storage, ion and guest exchange), non–linear optical activity, chiral networks, reactive networks, heterogeneous catalysis, luminescence, multifunctional materials and other properties. INDICE: Preface xi .1 Introduction to Coordination Polymers 1 .1.1 Coordination Space 1 .1.2 Coordination Polymer 3 .1.3 Development of Coordination Polymer 7 .1.4 Synthetic Methods 9 .1.5 Design of Coordination Polymer 13 .References 18 .2 Application of Coordination Polymers 23 .2.1 Introduction 23 .2.2 Gas Storage 24 .2.3 Catalysis 26 .2.4 Luminescence 28 .2.5 Redox Activity 29 .2.6 Magnetism 29 .2.6.1 Long–range Magnetic Ordering 29 .2.6.1.1 Molecule–based Magnets 32 .2.6.1.2 Single–chain Magnets 33 .2.6.2 Spin Crossover 33 .2.7 Acentric and Chiral Networks 35 .References 39 .3 Zinc(II) Coordination Polymers 43 .3.1 Introduction to Zinc(II) Coordination Polymers 43 .3.1.1 Coordination Polymers Constructed from Rigid Two–connecting Ligands 45 .3.1.1.1 Rod–type Ligands 45 .3.1.1.2 Angular, Rigid Two–connectors 49 .3.1.2 Coordination Polymers Constructed from Rigid, Trigonal Three–connectors 52 .3.1.3 Coordination Polymers Constructed from Carboxylates, Pyridine Carboxylates and Pyrazine Carboxylates 54 .3.1.4 Coordination Polymers Constructed from Secondary Building Blocks (SBUs) 57 .3.1.5 Coordination Polymers Constructed from Conformational Flexible Ligands 59 .3.1.6 Coordination Polymers Constructed from .Phosphate and Phosphonate Ligands 63 .3.2 Nano Zinc(II) Coordination Polymers 64 .3.3 Conclusion 70 .References 71 .4 Cadmium(II) Coordination Polymers 81 .4.1 Introduction to Cadmium (II) Coordination Polymers 81 .4.1.1 One–dimensional Coordination Polymers 82 .4.1.2 Two–dimensional Coordination Polymers 86 .4.1.3 Three–dimensional Coordination Polymers 93 .4.2 Nano Cadmium(II) Coordination Polymers 96 .4.3 Conclusion 102 .References 103 .5 Mercury(II) Coordination Polymers 113 .5.1 Introduction Mercury(II) Coordination Polymers 113 .5.1.1 One–dimensional Coordination Polymers 115 .5.1.2 Two–dimensional Coordination Polymers 120 .5.1.3 Three–dimensional Coordination Polymers 124 .5.2 Nano Mercury(II) Coordination Polymers 126 .5.3 Conclusion 131 .References 131 .6 Lead(II) Coordination Polymers 137 .6.1 Introduction 137 .6.2 Mono–donor Coordination Mode 139 .6.2.1 Discrete Complexes 139 .6.2.2 One–dimensional Coordination Polymers 141 .6.2.3 Two–dimensional Coordination Polymers 142 .6.2.4 Three–dimensional Coordination Polymers 142 .6.3 Bi–donor Coordination Polymers 143 .6.3.1 Bridging ( 2 1: 1) Mode 143 .6.3.1.1 Discrete Complexes 143 .6.3.1.2 One–dimensional Coordination Polymers 144 .6.3.1.3 Two–dimensional Coordination Polymers 144 .6.3.1.4 Three–dimensional Coordination Polymers 145 .6.4 Tri–donor Coordination Polymers 148 .6.4.1 Bridging ( 3 1: 2) Mode 148 .6.4.1.1 Two–dimensional Coordination Polymer 148 .6.4.1.2 Three–dimensional Coordination Polymers 148 .6.5 Tetra–donor Coordination 148 .6.5.1 Chelating, Bridging ( 3 1: 2: 1) Mode 148 .6.5.1.1 One–dimensional Coordination Polymers 150 .6.5.1.2 Two–dimensional Coordination Polymers 151 .6.5.1.3 Three–dimensional Coordination Polymers 152 .6.6 Nano Lead(II) Coordination Polymers 152 .6.7 Conclusion 164 .References 165 .7 Thallium(I) Coordination Polymers 177 .7.1 Introduction to Thallium(I) Coordination Polymers 177 .7.2 Thallium(I) Coordination Polymers 182 .7.2.1 One–dimensional Coordination Polymers with Secondary Interactions in TlI Coordination Sphere 183 .7.2.2 One–dimensional Coordination Polymers without Secondary Interactions in TlI Coordination Sphere 186 .7.2.3 Two–dimensional Coordination Polymers with Secondary Interactions in TlI Coordination Sphere 187 .7.2.4 Two–dimensional Coordination Polymers without Secondary Interactions in TlI Coordination Sphere 189 .7.2.5 Three–dimensional Coordination Polymers with Secondary Interactions in TlI Coordination Sphere 190 .7.2.6 Three–dimensional Coordination Polymers without Secondary Interactions in TlI Coordination Sphere 192 .7.3 Nano Thallium(I) Coordination Polymers 193 .7.4 Conclusion 198 .References 199 .8 Bismuth(III) Coordination Polymers 207 .8.1 Introduction to Bismuth Coordination Polymers 207 .8.2 Bismuth(III) Complexes with Monoaminopoly Carboxylate 211 .8.2.1 Bi(III) Complexes with Iminodiacetate Ligands 211 .8.2.2 Bi(III) Complexes with Nitrilotriacetate 212 .8.2.3 Bi(III) Complexes with 2–hydroxy– ethyliminodiacetate 214 .8.2.4 Bi(III) complexes with Pyridinedicarboxylate  Ligands 215 .8.3 Bismuth(III) Complexes with Diaminopolycarboxylate Ligands 217 .8.3.1 Bi(III) Complexes with Ethylenediaminetetraacetate 217 .8.3.1.1 Protonated Bi(III) Ethylenediaminetetraacetate Complexes 217 .8.3.1.2 Bi(III) Ethylenediaminetetraacetate Complexes with Alkali Metal and Ammonium Cations 218 .8.3.1.3 Bi(III) Ethylenediaminetetraacetate Complexes with Divalent Metal Cations 221 .8.3.1.4 Bi(III) Ethylenediaminetetraacetate Complexes with Protonated Organic Base Cations 222 .8.3.1.5 Bi(III) Ethylenediaminetetraacetates with Metal Complex Cations 222 .8.3.1.6 Mixed–ligand Bi(III) Ethylenediaminetetraacetate Complexes 224 .8.3.2 Bi(III) Complexes with other than edta4 diaminopolycarboxylate Ligands 226 .8.4 Bismuth Complexes with Polyaminopolycarboxylate Ligands 228 .8.4.1 Bi(III) Complexes with Diethylenetriaminepentaacetate Ligands and its Analogues 228 .8.4.2 Bi(III) Complexes with Triethylenetetraaminehexaacetate Ligands 229 .8.4.3 Bi(III) Complexes with Macrocyclic Polyaminopolycarboxylate Ligands 231 .8.5 Applications 232 .8.6 Nano Bismuth(III) Coordination Polymers 232 .8.7 Conclusion 238 .References 240 .9 Porous Main Group Coordination Polymers 247 .References 270 .10 S–block Coordination Polymers (Group1) 279 .10.1 Introduction 279 .10.2 Group 1(Alkali) Metal Coordination Polymers 280 .10.2.1 Neutral Oxygen Donor Lligands 280 .10.2.2 Anionic Oxygen Donor Ligands 283 .10.2.2.1 Alkoxides and Aryloxides 283 .10.2.2.2 Carboxylates 284 .10.2.2.3 Sulfonates and Nitro–derivatives 284 .10.2.2.4 Amino Acids 285 .10.2.2.5 Mixed O– and N–donors 286 .10.2.3 N–donor Ligands 287 .10.2.4 Carbon Donor Ligands 288 .10.2.5 Sulfur Donor Ligands 289 .10.3 Conclusion 291 .References 292 .11 S–block Coordination Polymers (Group2) 297 .11.1 Introduction 297 .11.2 Group 2(Alkaline Earth) Metal Coordination Polymers 299 .11.2.1 Neutral Oxygen Donor Ligands 300 .11.2.2 Anionic Oxygen Donor Ligands 301 .11.2.2.1 Beta–diketonates 301 .11.2.2.2 Alkoxides 302 .11.2.2.3 Carboxylates 302 .11.2.2.4 Phosphonates 304 .11.2.2.5 Sulfonates 305 .11.2.3 Mixed N– and O–donors 305 .11.2.4 N–donor Ligands 306 .11.2.5 Carbon Donor Ligands 308 .11.2.6 Sulfur Donor Ligands 309 .11.3 Conclusion 310 .References 311

• ISBN: 978-1-119-37023-9
• Editorial: John Wiley & Sons
• Encuadernacion: Cartoné
• Páginas: 272
• Fecha Publicación: 17/03/2017
• Nº Volúmenes: 1
• Idioma: Inglés