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Submit a ProposalMetal-Organic Frameworks with Heterogeneous Structures
 | By Ali Morsali and Kayhaneh Berijani Copyright: 2021 | Status: Published ISBN: 9781119792048 | Hardcover | 224 pages | 61 illustrations Price: $195 USD  |
One Line Description
A unique book that sheds light on Metal-Organic Frameworks complex systems that often display behaviors that surprise and cannot be easily described.
Audience
This book will be beneficial for chemists, materials engineers, advanced postgraduate and graduate students, researchers and specialists who are working in the area of materials design and their chemistry, porous crystalline materials, coordination polymers, hybrid and functional materials, as well as industry professionals, such as those working on selective catalysis and adsorption-separation, optics, gas capture, processes of biological and pharmaceutical.
This book will be beneficial for chemists, materials engineers, advanced postgraduate and graduate students, researchers and specialists who are working in the area of materials design and their chemistry, porous crystalline materials, coordination polymers, hybrid and functional materials, as well as industry professionals, such as those working on selective catalysis and adsorption-separation, optics, gas capture, processes of biological and pharmaceutical.
Description
In this book, MOF-based heterostructures technology with key characteristics is completely analyzed and the current state-of-the-art is discussed. The authors focus on the complex heterostructures promoted by MOFs with advantage of their recent new advances for various applications with particular emphasis on their design. As an extension of the design and synthesis, the shaping technology of heterostructure MOFs is also of great significance to the future practical applications in industry (adsorption/desorption, gas storage, catalysis, conductivity, optical activity) of this class of complex porous materials. As this unique book covers all of the aspects of complexity in MOFs with heterogeneous structures, it serves as an essential reference to the concepts of introducing complexity to designing the future new platforms of materials with advanced and superior properties.
This important compact book provides the reader with:
• The principal aspects of heterogeneity that produce complexity in MOFs, their
effects in the structure chemistry, performance and applications
• The effects of complexities on the structure of metal-organic frameworks
• The roles of complexities on metal-organic frameworks applications
• Explanation of synthesis strategies of the complex heterostructure MOFs.
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In this book, MOF-based heterostructures technology with key characteristics is completely analyzed and the current state-of-the-art is discussed. The authors focus on the complex heterostructures promoted by MOFs with advantage of their recent new advances for various applications with particular emphasis on their design. As an extension of the design and synthesis, the shaping technology of heterostructure MOFs is also of great significance to the future practical applications in industry (adsorption/desorption, gas storage, catalysis, conductivity, optical activity) of this class of complex porous materials. As this unique book covers all of the aspects of complexity in MOFs with heterogeneous structures, it serves as an essential reference to the concepts of introducing complexity to designing the future new platforms of materials with advanced and superior properties.
This important compact book provides the reader with:
• The principal aspects of heterogeneity that produce complexity in MOFs, their
effects in the structure chemistry, performance and applications
• The effects of complexities on the structure of metal-organic frameworks
• The roles of complexities on metal-organic frameworks applications
• Explanation of synthesis strategies of the complex heterostructure MOFs.
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Author / Editor Details
Ali Morsali, PhD is Master in inorganic chemistry at 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 and published 4 books under the Wiley-Scrivener imprint. He has received numerous national awards. Amongst his research interests are coordination chemistry and metal- organic frameworks.
Ali Morsali, PhD is Master in inorganic chemistry at 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 and published 4 books under the Wiley-Scrivener imprint. He has received numerous national awards. Amongst his research interests are coordination chemistry and metal- organic frameworks.
Kayhaneh Berijani, PhD earned her PhD in inorganic chemistry from the University of Zanjan. After graduating, she worked as a postdoctoral researcher with Prof. Ali Morsali on chiral MOFs field at Tarbiat Modares University. Her current research interests are chiral metal-organic frameworks, green chemistry, chiral materials and asymmetric processes.
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Table of Contents
Preface
1. Introduction to Functional Metal–Organic Frameworks
1.1 Coordination Polymers
1.2 Metal–Organic Frameworks
1.3 Functional Metal–Organic Frameworks
References
2. Amine Decorated Metal–Organic Frameworks
2.1 General Chemical Properties of Amine Function
2.2 Function–Application Properties
2.3 Function–Structure Properties
References
3. Azo and Azine Decorated Metal–Organic Frameworks
3.1 General Chemical Properties of Azine and Azo Functions
3.2 Function–Application Properties
3.3 Function-Structure Properties
References
4. Imidazolium and Pyridinium Decorated Metal-Organic Frameworks
4.1 Imidazolium Functionalized Metal–Organic Frameworks
4.1.1 General Chemical Properties of Imidazolium Function
4.1.2 Function–Application Properties
4.1.3 Function–Structure Properties
4.2 Pyridinium Functionalized Metal–Organic Frameworks
4.2.1 General Chemical Properties of Pyridinium Function
4.2.2 Function–Application Properties
4.2.3 Function–Structure Properties
References
5. Heterocyclic Azine Decorated Metal-Organic Frameworks
5.1 General Chemical Properties of Heterocyclic Azine Functions
5.2 Function–Application Properties
5.3 Function–Structure Properties
References
6 Heterocyclic Azole Decorated Metal-Organic Frameworks
6.1 General Chemical Properties of Heterocyclic Azole Functions
6.2 Function–Application Properties
6.3 Function–Structure Properties
References
7. Functional Metal–Organic Frameworks by Oxygen and Sulfur Based Functions
7.1 Functionalized Metal–Organic Frameworks by Oxygen Based Functions
7.1.1 Function–Application Properties
7.1.2 Function–Structure Properties
7.2 Functionalized Metal–Organic Frameworks by Sulfur Based Functions
7.2.1 Functionalized Metal–Organic Frameworks by Thiol and Sulfide Functions
7.2.2 Functionalized Metal–Organic Frameworks by Sulfonate-Sulfonic Acid Function
7.2.3 Functionalized Metal–Organic Frameworks by Other S-Based Functions
References
8. Urea and Amide Decorated Metal-Organic Frameworks
8.1 Functionalized Metal–Organic Frameworks by Amide Function
8.1.1 General Chemical Properties of Amide Function
8.1.2 Function–Application Properties
8.1.3 Function–Structure Properties
8.2 Functionalized Metal–Organic Frameworks by Urea Function
8.2.1 General Chemical Properties of Urea Function
8.2.2 Function–Application Properties
8.2.3 Structure–Function Properties
8.3 Functionalized Metal–Organic Frameworks by Squaramide Function
References
9. Carbonyl, Carboxy and Imide Functionalized Metal–Organic Frameworks
9.1 Functionalized Metal–Organic Frameworks by Carbonyl Function
9.1.1 General Chemical Properties of Carbonyl Functional Group
9.1.2 Function–Application Properties
9.1.3 Function–Structure Properties
9.2 Functionalized Metal–Organic Frameworks by Carboxy Function
9.2.1 General Chemical Properties of Carboxy Function
9.2.2 Synthesis of Functionalized Metal-Organic Frameworks with Free Carboxy Function
9.2.3 Function–Application Properties
9.2.4 Function–Structure Properties
9.3 Functionalized Metal–Organic Frameworks by Imide Function
9.3.1 General Chemical Properties of Imide Function
9.3.2 Function–Application Properties
References
10. Fluorine and Phosphonate Functional Metal–Organic Frameworks
10.1 Functionalized Metal–Organic Frameworks by Phosphonic Acid/Phosphonate Functions
10.2 Functionalized Metal–Organic Frameworks by Fluorine Function
References
Index
Back to Top
Preface
1. Introduction to Functional Metal–Organic Frameworks
1.1 Coordination Polymers
1.2 Metal–Organic Frameworks
1.3 Functional Metal–Organic Frameworks
References
2. Amine Decorated Metal–Organic Frameworks
2.1 General Chemical Properties of Amine Function
2.2 Function–Application Properties
2.3 Function–Structure Properties
References
3. Azo and Azine Decorated Metal–Organic Frameworks
3.1 General Chemical Properties of Azine and Azo Functions
3.2 Function–Application Properties
3.3 Function-Structure Properties
References
4. Imidazolium and Pyridinium Decorated Metal-Organic Frameworks
4.1 Imidazolium Functionalized Metal–Organic Frameworks
4.1.1 General Chemical Properties of Imidazolium Function
4.1.2 Function–Application Properties
4.1.3 Function–Structure Properties
4.2 Pyridinium Functionalized Metal–Organic Frameworks
4.2.1 General Chemical Properties of Pyridinium Function
4.2.2 Function–Application Properties
4.2.3 Function–Structure Properties
References
5. Heterocyclic Azine Decorated Metal-Organic Frameworks
5.1 General Chemical Properties of Heterocyclic Azine Functions
5.2 Function–Application Properties
5.3 Function–Structure Properties
References
6 Heterocyclic Azole Decorated Metal-Organic Frameworks
6.1 General Chemical Properties of Heterocyclic Azole Functions
6.2 Function–Application Properties
6.3 Function–Structure Properties
References
7. Functional Metal–Organic Frameworks by Oxygen and Sulfur Based Functions
7.1 Functionalized Metal–Organic Frameworks by Oxygen Based Functions
7.1.1 Function–Application Properties
7.1.2 Function–Structure Properties
7.2 Functionalized Metal–Organic Frameworks by Sulfur Based Functions
7.2.1 Functionalized Metal–Organic Frameworks by Thiol and Sulfide Functions
7.2.2 Functionalized Metal–Organic Frameworks by Sulfonate-Sulfonic Acid Function
7.2.3 Functionalized Metal–Organic Frameworks by Other S-Based Functions
References
8. Urea and Amide Decorated Metal-Organic Frameworks
8.1 Functionalized Metal–Organic Frameworks by Amide Function
8.1.1 General Chemical Properties of Amide Function
8.1.2 Function–Application Properties
8.1.3 Function–Structure Properties
8.2 Functionalized Metal–Organic Frameworks by Urea Function
8.2.1 General Chemical Properties of Urea Function
8.2.2 Function–Application Properties
8.2.3 Structure–Function Properties
8.3 Functionalized Metal–Organic Frameworks by Squaramide Function
References
9. Carbonyl, Carboxy and Imide Functionalized Metal–Organic Frameworks
9.1 Functionalized Metal–Organic Frameworks by Carbonyl Function
9.1.1 General Chemical Properties of Carbonyl Functional Group
9.1.2 Function–Application Properties
9.1.3 Function–Structure Properties
9.2 Functionalized Metal–Organic Frameworks by Carboxy Function
9.2.1 General Chemical Properties of Carboxy Function
9.2.2 Synthesis of Functionalized Metal-Organic Frameworks with Free Carboxy Function
9.2.3 Function–Application Properties
9.2.4 Function–Structure Properties
9.3 Functionalized Metal–Organic Frameworks by Imide Function
9.3.1 General Chemical Properties of Imide Function
9.3.2 Function–Application Properties
References
10. Fluorine and Phosphonate Functional Metal–Organic Frameworks
10.1 Functionalized Metal–Organic Frameworks by Phosphonic Acid/Phosphonate Functions
10.2 Functionalized Metal–Organic Frameworks by Fluorine Function
References
Index
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