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E-raamat: Pillared Metal-Organic Frameworks: Properties and Applications

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(Tarbiat Modares University, Tehran, Iran), (Tarbiat Modares University, Tehran, Iran)
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  • Ilmumisaeg: 16-Apr-2019
  • Kirjastus: Wiley-Scrivener
  • Keel: eng
  • ISBN-13: 9781119460398
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Pillared Metal-Organic Frameworks: Properties and ApplicationsSuurem pilt
  • Formaat: PDF+DRM
  • Ilmumisaeg: 16-Apr-2019
  • Kirjastus: Wiley-Scrivener
  • Keel: eng
  • ISBN-13: 9781119460398
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In the last two decades, metal-organic frameworks (MOFs) have provoked considerable interest due to their potential applications in different fields such as catalysis, gas storage and sensing. The most important advantages of MOFs over other porous materials is the ability of tailoring their pore size, functionality and even the topology of the framework by rational selection of the molecular building blocks. Therefore, many chemists have tried to engineer the structure of MOFs to achieve specific functions.

Pillared metal organic frameworks are a class of MOFs composed of inorganic secondary building units (SBUs) and two sets of organic linkers, generally oxygen- and nitrogen-donor ligands. Typically, in the structure of pillared MOFs, the oxygen-donor struts link the metal clusters into a two-dimensional (2D) sheet and the N-donor struts pillar the sheets to generate a three-dimensional (3D) framework. Thus, the construction of MOFs by utilizing two sets of organic linkers could provide an extra possibility for further tuning of MOF’s pore walls. A variety of functional groups including imine, amide and heterocycles were successfully incorporated into bidentate pillar ligand skeleton. Interestingly, by using pillaring linkers with different length, a wide diversity of metal-organic frameworks with tunable pore dimensions and topologies can be obtained. In this book, we introduce pillared metal organic frameworks with their properties and applications.

Preface ix
Abbreviations xi
1 Introduction to Metal-Organic Frameworks 1(44)
1.1 What are the Metal-Organic Frameworks?
1(4)
1.2 Synthesis of Metal-Organic Frameworks
5(1)
1.3 Structural Highlights of Metal-Organic Frameworks
6(4)
1.4 Expansion of Metal-Organic Frameworks Structures
10(1)
1.5 High Thermal and Chemical Stability
11(1)
1.6 Applications of Metal-Organic Frameworks
12(28)
1.6.1 Gas (Hydrogen and Methane) Storage in MOFs
13(3)
1.6.1.1 Hydrogen Storage in MOFs
14(2)
1.6.1.2 Methane Storage in MOFs
16(1)
1.6.2 Carbon Dioxide Capture in MOFs
16(4)
1.6.2.1 Capacity for CO2
17(1)
1.6.2.2 Enthalpy of Adsorption
18(1)
1.6.2.3 Selectivity for CO2
19(1)
1.6.3 Post-Combustion Capture
20(5)
1.6.3.1 Ideal Adsorbed Solution Theory (IAST)
21(1)
1.6.3.2 Metal-Organic Frameworks for CO2/N2 Separation
21(4)
1.6.4 Pre-Combustion Capture
25(3)
1.6.4.1 Metal-Organic Frameworks as Adsorbents
26(2)
1.6.5 Selective Gas Adsorption in MOFs
28(1)
1.6.6 Useful Gas Separations in MOFs
29(1)
1.6.7 Catalysis in MOFs
30(1)
1.6.8 Magnetic Properties of MOFs
30(1)
1.6.9 Luminescence and Sensors in MOFs
31(6)
1.6.9.1 Luminescence in MOFs
32(2)
1.6.9.2 Sensors in MOFs
34(3)
1.6.10 Drug Storage and Delivery in MOFs
37(2)
1.6.10.1 Drug-Delivery Methods
37(2)
1.6.11 MOFs; Precursors for Preparation of Nano-Materials
39(1)
1.7 Conclusion
40(1)
References
40(5)
2 Pillar-Layer Metal-Organic Frameworks 45(14)
2.1 Introduction
45(4)
2.2 Topology and Diversity in Pillar-Layered MOFs
49(2)
2.3 Synthesis Methods in Pillar-Layered MOFs
51(4)
2.4 Linkers in Pillar-Layered MOFs
55(1)
2.5 Conclusion
55(1)
References
56(3)
3 Rigid and Flexible Pillars 59(18)
3.1 Introduction
59(12)
3.2 Conclusion
71(1)
References
71(6)
4 Introduction to N-donor Pillars 77(80)
4.1 Introduction
77(1)
4.2 Bipyridine
78(53)
4.3 Dabco
131(3)
4.4 Imidazole and Pyrazole
134(4)
4.5 Triazole and Tetrazole
138(3)
4.6 Pyrazine and Pipyrazine
141(2)
4.7 Amide, Imide, Amin and Azine/Azo Spacer
143(6)
4.8 Conclusion
149(1)
References
150(7)
5 Introduction to Aromatic and Aliphatic Pillars 157(20)
5.1 Introduction
157(5)
5.2 Non-Interpentrated Frameworks
162(3)
5.3 Frameworks with Interpenetration
165(1)
5.4 Control over Interpenetration
166(4)
5.5 Conclusion
170(1)
References
171(6)
6 Introduction to 0-Donor Pillars 177(78)
6.1 Introduction
177(74)
6.2 Conclusion
251(1)
References
251(4)
7 Stability and Interpenetration in Pillar-Layer MOFs 255(20)
7.1 Stability in Pillar-Layer MOFs
255(7)
7.2 Interpenetration in Pillar-Layer MOFs
262(7)
7.3 Conclusion
269(1)
References
270(5)
8 Properties and Applications of Pillar-Layer MOFs 275(66)
8.1 Introduction
275(1)
8.2 Gas Storage and Separation in Pillar-Layer MOFs
276(13)
8.2.1 Two Dimensional Networks Based on Mixed Linkers
278(4)
8.2.1.1 2D Interdigitated Networks
279(1)
8.2.1.2 2D Pillared-Bilayer Networks
280(2)
8.2.2 Three Dimensional Frameworks with Mixed Linkers
282(16)
8.2.2.1 Anionic Linker (Other Than Carboxylate) Based Frameworks
282(2)
8.2.2.2 Carboxylate Linker Based Frameworks
284(5)
8.3 Catalysis in Pillar-Layer MOFs
289(9)
8.4 Adsorptive Removal and Separation of Chemicals in Pillar-Layer MOFs
298(24)
8.4.1 Adsorptive Removal of Harmful Gases
302(8)
8.4.2 Capture of Volatile Organic Compounds
310(7)
8.4.3 Adsorptive Removal of Iodine
317(5)
8.5 Sensing in Pillar-Layer MOFs
322(7)
8.6 Conclusion
329(1)
References
329(12)
Glossary 341(8)
Subject Index 349
Lida Hashemi is a postdoctoral researcher at Tarbiat Modarers University, Tehran, Iran. She obtained her PhD in inorganic chemistry from the same university in 2014. She has published 30 articles in international journals and has one patent to her name. Her research interests are coordination chemistry, nanotechnology and metal-organic frameworks.

Ali Morsali is Master in Inorganic Chemistry in Tarbiat Modares University, Tehran, Iran. He obtained his PhD in 2003 in Inorganic Chemistry from the same university. He has published more than 400 articles in international journals as well as 5 patents. He has received numerous national awards. Amongst his research interests are coordination chemistry and metal-organic frameworks.
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