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Author: Noelle Ruiz Catarineu
Publisher:
ISBN:
Category :
Languages : en
Pages : 119
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Book Description
Described in this dissertation are a range of methods for expanding the complexity of materials in the class of metal-organic frameworks (MOFs). From their discovery in the mid-1990's until today, metal-organic frameworks have largely been built from a narrow set of building blocks: symmetric, aromatic, carboxylates and first row transition or rare earth metals. While much work has been devoted to investigating the scope of their possible applications, more fundamental understanding of their chemistry is needed for the full potential of this class of materials to be realized. In addition to their crystallinity and porosity, the primary reason for the success of metal-organic frameworks in fields ranging from gas storage to catalysis stems from their inherent tunability. Metal-organic frameworks, in contrast to other porous materials such as zeolites, are modular in that they are built from discrete organic and inorganic components and can therefore be tailored to specific purposes. Increasing the attainable complexity of these materials allows for greater optimization toward existing applications and for exploring previously undiscovered areas. Complexity in solid-state materials is introduced through heterogeneity of composition or distribution. For metal-organic frameworks, this heterogeneity is manifested either in the backbone composing the underlying network or in the functionalities exposed to the pore space. Both approaches are investigated in this dissertation. Heterogeneity of the backbone rests in the diversity of the organic and inorganic building units. Heterogeneity of the pore space is provided by functionalization of organic and inorganic structural building units without altering their structural properties. Chapter One presents an introduction to rational design of metal-organic frameworks encompassing the context and background for this work. The building block approach provides control of metal-organic framework structure, stability, and functionality. Both inorganic and organic building units are available for modification. Variations in linker length, geometry, and connectivity correlate with changes in the extended structure. Choice of coordinating group is another element of control. Much remains to be investigated in terms of linkage type in metal-organic frameworks by exploring new coordinating groups. Concerning the metal components, the multifarious clusters and chains serving as secondary building units (SBUs) have implications for the structure, stability, and function of these materials. The identity of the metal ions comprising these secondary building units impacts these aspects as well. Heterogeneity of metal-organic framework backbones has been achieved in mixed linker and mixed metal systems. Strategies to achieve pure phases of materials with mixed components include synthesis from a mixture of starting materials as well as post-synthetic modification. Inside heterogeneous pore spaces, desired functionalities coordinate to the metals of the frameworks or are sidechains of the organic linkers. An analysis of the structure and property implications of constructing metal-organic frameworks from heterotopic linkers, meaning those linkers with non-identical coordinating groups, had not been reported. The lack of investigation in this area was the impetus for the research presented in Chapters Two and Three. Chapter Two describes the design, synthesis, and characterization of a heterotritopic linker for metal-organic frameworks. This compound bears a carboxylic acid, catechol, and pyridone and was not known in the literature. The original and optimized synthetic routes are given. The linker is synthesized reproducibly on gram scale in three steps with a single column chromatography purification. The analytical data for this linker are given, including the mass spectrometry, one-dimensional and two-dimensional nuclear magnetic resonance, and infrared spectra. The reasoning behind the choice of metrics and coordinating groups is described. Chapter Three details the synthesis, structure elucidation and refinement, and properties of a metal-organic framework constructed from a heterotritopic linker and zinc(II), termed MOF-910. Despite the asymmetry of the linker, MOF-910 is both highly crystalline and symmetric. Synthetic conditions for crystallization of the heterotritopic linker with zinc(II) required an added base, such as triethylamine. The material is highly porous with a Brunauer-Emmett-Teller surface area of 2,120 m2 g-1and hexagonal channels 21 Å in diameter. The material is remarkably thermally and chemically stable for a zinc-based metal-organic framework. Integrity of the framework is maintained up to 320 °C and under acidic and basic aqueous conditions. The catechol moiety undergoes oxidation to the corresponding semiquinone during the metal-organic framework synthesis. The electron paramagnetic resonance spectrum indicates a ligand-centered radical. Chapter Four concerns the applications and reticular chemistry insights uncovered by MOF-910. One focus is the prediction and control of structure of metal-organic frameworks through lower symmetry and heterotopic linkers. The process for reducing MOF-910 to its underlying topological network is explained. The tto (ttriangles. tetrahedra, octahedra) net, of which MOF-910 is the first representation, is described. The tendency of heterotopic linkers to form helical secondary building units is investigated. The dependence of helical pitch on the distance between the most proximal coordinating groups in asymmetric polytopic linkers is discussed. The contributions of these discoveries to the field of reticular chemistry are stated. The electrochromic and gas adsorption behavior of MOF-910 are described as well. Treatment with a mild oxidant converts colorless crystals to bright red with no change in structure discernible by single-crystal X-ray diffraction and no change in surface area. Exposure to a mild reductant causes red crystals to lose color. Chapter Five focuses on functionalization of metal-organic frameworks constructed from tetrakis(4-carboxyphenyl)porphyrin and zirconium(IV) clusters. The introduction of functionality through the organic ligand is described in MOF-525 and MOF-545. Since the porphyrin core is not involved in structure formation of these metal-organic frameworks, additional reactive sites were installed in these frameworks by coordination to the porphyrin pyrroles. The synthetic conditions for constructing zirconium(IV) metal-organic frameworks with porphyrin linkers bound to aluminum(III), chromium(III), manganese(III), iron(III), cobalt(III), nickel(II), copper(II), and zinc(II) are reported. The synthesis of the aluminum(III) and chromium(III) linkers is given. The activation conditions for these generally difficult to evacuate mesoporous materials are listed. The ability of these metalated porphyrin materials to capture toxic gases is reported.
Author: Noelle Ruiz Catarineu
Publisher:
ISBN:
Category :
Languages : en
Pages : 119
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Book Description
Described in this dissertation are a range of methods for expanding the complexity of materials in the class of metal-organic frameworks (MOFs). From their discovery in the mid-1990's until today, metal-organic frameworks have largely been built from a narrow set of building blocks: symmetric, aromatic, carboxylates and first row transition or rare earth metals. While much work has been devoted to investigating the scope of their possible applications, more fundamental understanding of their chemistry is needed for the full potential of this class of materials to be realized. In addition to their crystallinity and porosity, the primary reason for the success of metal-organic frameworks in fields ranging from gas storage to catalysis stems from their inherent tunability. Metal-organic frameworks, in contrast to other porous materials such as zeolites, are modular in that they are built from discrete organic and inorganic components and can therefore be tailored to specific purposes. Increasing the attainable complexity of these materials allows for greater optimization toward existing applications and for exploring previously undiscovered areas. Complexity in solid-state materials is introduced through heterogeneity of composition or distribution. For metal-organic frameworks, this heterogeneity is manifested either in the backbone composing the underlying network or in the functionalities exposed to the pore space. Both approaches are investigated in this dissertation. Heterogeneity of the backbone rests in the diversity of the organic and inorganic building units. Heterogeneity of the pore space is provided by functionalization of organic and inorganic structural building units without altering their structural properties. Chapter One presents an introduction to rational design of metal-organic frameworks encompassing the context and background for this work. The building block approach provides control of metal-organic framework structure, stability, and functionality. Both inorganic and organic building units are available for modification. Variations in linker length, geometry, and connectivity correlate with changes in the extended structure. Choice of coordinating group is another element of control. Much remains to be investigated in terms of linkage type in metal-organic frameworks by exploring new coordinating groups. Concerning the metal components, the multifarious clusters and chains serving as secondary building units (SBUs) have implications for the structure, stability, and function of these materials. The identity of the metal ions comprising these secondary building units impacts these aspects as well. Heterogeneity of metal-organic framework backbones has been achieved in mixed linker and mixed metal systems. Strategies to achieve pure phases of materials with mixed components include synthesis from a mixture of starting materials as well as post-synthetic modification. Inside heterogeneous pore spaces, desired functionalities coordinate to the metals of the frameworks or are sidechains of the organic linkers. An analysis of the structure and property implications of constructing metal-organic frameworks from heterotopic linkers, meaning those linkers with non-identical coordinating groups, had not been reported. The lack of investigation in this area was the impetus for the research presented in Chapters Two and Three. Chapter Two describes the design, synthesis, and characterization of a heterotritopic linker for metal-organic frameworks. This compound bears a carboxylic acid, catechol, and pyridone and was not known in the literature. The original and optimized synthetic routes are given. The linker is synthesized reproducibly on gram scale in three steps with a single column chromatography purification. The analytical data for this linker are given, including the mass spectrometry, one-dimensional and two-dimensional nuclear magnetic resonance, and infrared spectra. The reasoning behind the choice of metrics and coordinating groups is described. Chapter Three details the synthesis, structure elucidation and refinement, and properties of a metal-organic framework constructed from a heterotritopic linker and zinc(II), termed MOF-910. Despite the asymmetry of the linker, MOF-910 is both highly crystalline and symmetric. Synthetic conditions for crystallization of the heterotritopic linker with zinc(II) required an added base, such as triethylamine. The material is highly porous with a Brunauer-Emmett-Teller surface area of 2,120 m2 g-1and hexagonal channels 21 Å in diameter. The material is remarkably thermally and chemically stable for a zinc-based metal-organic framework. Integrity of the framework is maintained up to 320 °C and under acidic and basic aqueous conditions. The catechol moiety undergoes oxidation to the corresponding semiquinone during the metal-organic framework synthesis. The electron paramagnetic resonance spectrum indicates a ligand-centered radical. Chapter Four concerns the applications and reticular chemistry insights uncovered by MOF-910. One focus is the prediction and control of structure of metal-organic frameworks through lower symmetry and heterotopic linkers. The process for reducing MOF-910 to its underlying topological network is explained. The tto (ttriangles. tetrahedra, octahedra) net, of which MOF-910 is the first representation, is described. The tendency of heterotopic linkers to form helical secondary building units is investigated. The dependence of helical pitch on the distance between the most proximal coordinating groups in asymmetric polytopic linkers is discussed. The contributions of these discoveries to the field of reticular chemistry are stated. The electrochromic and gas adsorption behavior of MOF-910 are described as well. Treatment with a mild oxidant converts colorless crystals to bright red with no change in structure discernible by single-crystal X-ray diffraction and no change in surface area. Exposure to a mild reductant causes red crystals to lose color. Chapter Five focuses on functionalization of metal-organic frameworks constructed from tetrakis(4-carboxyphenyl)porphyrin and zirconium(IV) clusters. The introduction of functionality through the organic ligand is described in MOF-525 and MOF-545. Since the porphyrin core is not involved in structure formation of these metal-organic frameworks, additional reactive sites were installed in these frameworks by coordination to the porphyrin pyrroles. The synthetic conditions for constructing zirconium(IV) metal-organic frameworks with porphyrin linkers bound to aluminum(III), chromium(III), manganese(III), iron(III), cobalt(III), nickel(II), copper(II), and zinc(II) are reported. The synthesis of the aluminum(III) and chromium(III) linkers is given. The activation conditions for these generally difficult to evacuate mesoporous materials are listed. The ability of these metalated porphyrin materials to capture toxic gases is reported.
Author: Masoud Mozafari
Publisher: Woodhead Publishing
ISBN: 0128169842
Category : Medical
Languages : en
Pages : 584
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Book Description
Metal-Organic Frameworks for Biomedical Applications is a comprehensive, authoritative reference that offers a substantial and complete treatment of published results that have yet to be critically reviewed. It offers a summary of current research and provides in-depth understanding of the role of metal-organic frameworks in biomedical engineering. The title consists of twenty-two chapters presented by leading international researchers in the field. Chapters are arranged by target-application in biomedical engineering, allowing medical and pharmaceutic specialists to translate current materials and engineering science on metal-organic frameworks into their work. Presents the state-of-the art in metal-organic frameworks for biomedical applications Offers comprehensive treatment of metal-organic frameworks that is useful to pharmaceutic and medical experts who are non-specialists in materials science Helps materials scientists and engineers understand the needs of biomedical engineering Critically-reviews published results and current research in the field
Author: Ali Morsali
Publisher: John Wiley & Sons
ISBN: 1119640431
Category : Science
Languages : en
Pages : 256
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Book Description
Owing to the extensive interest in construction of functional metal organic frameworks (FMOFs), this book discusses the roles of functional groups on the structure and application of metal organic frameworks (MOFs). The contents of the book are classified based on the structural and chemical properties of organic functions, in order to make readers able to compare the different effects of each function on the structure and application of the MOFs. In each chapter, the chemical properties of applied functional groups are gathered to give deeper insight into the roles of organic functions in the structure and application of MOFs. In the function-application properties, the authors discuss how a functional group can dominate the host-guest chemistry of the MOFs and how this host-guest chemistry can expand the effectiveness and efficiency of the material in different fields of applications. Finally, function-structure properties are discussed. In function-application properties, it is discussed how a functional group can affect the topology, porosity, flexibility and stability of the framework. The features of this subject are novel and are presented for the first time.
Author: Omar M. Yaghi
Publisher: John Wiley & Sons
ISBN: 3527821104
Category : Science
Languages : en
Pages : 684
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Book Description
A concise introduction to the chemistry and design principles behind important metal-organic frameworks and related porous materials Reticular chemistry has been applied to synthesize new classes of porous materials that are successfully used for myraid applications in areas such as gas separation, catalysis, energy, and electronics. Introduction to Reticular Chemistry gives an unique overview of the principles of the chemistry behind metal-organic frameworks (MOFs), covalent organic frameworks (COFs), and zeolitic imidazolate frameworks (ZIFs). Written by one of the pioneers in the field, this book covers all important aspects of reticular chemistry, including design and synthesis, properties and characterization, as well as current and future applications Designed to be an accessible resource, the book is written in an easy-to-understand style. It includes an extensive bibliography, and offers figures and videos of crystal structures that are available as an electronic supplement. Introduction to Reticular Chemistry: -Describes the underlying principles and design elements for the synthesis of important metal-organic frameworks (MOFs) and related materials -Discusses both real-life and future applications in various fields, such as clean energy and water adsorption -Offers all graphic material on a companion website -Provides first-hand knowledge by Omar Yaghi, one of the pioneers in the field, and his team. Aimed at graduate students in chemistry, structural chemists, inorganic chemists, organic chemists, catalytic chemists, and others, Introduction to Reticular Chemistry is a groundbreaking book that explores the chemistry principles and applications of MOFs, COFs, and ZIFs.
Author: Leonard R. MacGillivray
Publisher: John Wiley & Sons
ISBN: 1118931580
Category : Science
Languages : en
Pages : 1210
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Book Description
Metal-Organic Frameworks (MOFs) are crystalline compounds consisting of rigid organic molecules held together and organized by metal ions or clusters. Special interests in these materials arise from the fact that many are highly porous and can be used for storage of small molecules, for example H2 or CO2. Consequently, the materials are ideal candidates for a wide range of applications including gas storage, separation technologies and catalysis. Potential applications include the storage of hydrogen for fuel-cell cars, and the removal and storage of carbon dioxide in sustainable technical processes. MOFs offer the inorganic chemist and materials scientist a wide range of new synthetic possibilities and open the doors to new and exciting basic research. Metal-Organic Frameworks Materials provides a solid basis for the understanding of MOFs and insights into new inorganic materials structures and properties. The volume also reflects progress that has been made in recent years, presenting a wide range of new applications including state-of-the art developments in the promising technology for alternative fuels. The comprehensive volume investigates structures, symmetry, supramolecular chemistry, surface engineering, recognition, properties, and reactions. The content from this book will be added online to the Encyclopedia of Inorganic and Bioinorganic Chemistry: http://www.wileyonlinelibrary.com/ref/eibc
Author: Victoria Samanidou
Publisher: MDPI
ISBN: 303928486X
Category : Science
Languages : en
Pages : 198
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Book Description
Metal–organic frameworks are among the most promising novel materials. The concept of MOFs was first introduced in 1990. They were actually initially used in catalysis, gas separation, membranes, electrochemical sensors. Later on, they were introduced as SPE sorbents for PAHs (Polycyclic Aromatic Hydrocarbons) in environmental water samples, then the range expanded to the field of analytical chemistry, both in chromatographic separation and sample preparation, with great success in, e.g., SPE and SPME (Solid Phase Mico-extraction). Since then, the number of analytical applications implementing MOFs as sorbents in sorptive sample preparation approaches is increasing. Τhis is reinforced by the fact that, at least theoretically, an infinite number of structures can be designed and synthesized, thus making tuneability one of the most unique characteristics of MOF materials. Moreover, they have been designed in various shapes, such as columns, fibers, and films, so that they can meet more analytical challenges with improved analytical features.Their exceptional properties attracted the interest of analytical chemists who have taken advantage of the unique structures and properties and have already introduced them in several sample pretreatment techniques, such as solid phase extraction, dispersive SPE, magnetic solid phase extraction, solid phase microextraction, stir bar sorptive extraction, etc.
Author: Ali Morsali
Publisher: John Wiley & Sons
ISBN: 1119792045
Category : Science
Languages : en
Pages : 226
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Book Description
METAL-ORGANIC FRAMEWORKS WITH HETEROGENEOUS STRUCTURES A unique book that sheds light on Metal-Organic Frameworks complex systems that often display behaviors that surprise and cannot be easily described. 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. 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.
Author: Corinne An-Li Allen
Publisher:
ISBN: 9781321361650
Category :
Languages : en
Pages : 171
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Book Description
Metal-Organic Frameworks (MOFs) are porous coordination polymers with the potential to excel in catalysis and gas storage/separation. This dissertation will first discuss relevant types of MOFs, their characteristics, and previous functionalization methods. To fully gauge the utility of MOFs, novel materials with tunable properties are required as are appropriate design strategies to create these materials. Of specific interest is MOFs embedded with secondary metal binding groups. Chapter 2 will discuss a mild method to incorporate these functional groups into MOFs. The utilization of photocleavable protecting groups, a nitrobenzyl ether masking an aryl hydroxyl group, allows for the liberation of secondary metal binding sites upon photoirradiation. By combining mixed MOF systems with photochemical and chemical modification methods, multifunctional materials can be accessed from a single starting MOF. Exploration of new postsynthetic modification reactions is explored in Chapter 3. Initial studies focused on a radical initiated photochemical-click reaction to modify a terminal alkene with a free thiol to create a thioether. Depending on the chemical stability and pore size of the MOF material, this reaction was moderately successful at best. Additionally, optimization proved to be difficult due to the number of chemical species present during the course of the reaction. A simpler click Diels-Alder cycloaddition was studied as an alternative route to modify a terminal alkene embedded inside the MOF. The cycloaddition was found to proceed only if there was sufficient space available within the MOF pores and around the alkene moiety. Finally, in Chapter 4, chemically crosslinked organic ligands are studied to probe the tolerance of certain MOFs for geometrically restricted components. Extended oligomeric ligands based on these criteria are also discussed. Even using ligands with up to four organic struts tethered together, the canonical IRMOF structure can still be formed. This indicates that the limitations of coordination polymers are much less stringent than originally thought.
Author: Shengqian Ma
Publisher: World Scientific
ISBN: 9813226749
Category : Science
Languages : en
Pages : 730
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Book Description
This title takes researchers in as well as out of the field of metal-organic framework (MOF) and then guides them on a journey to rediscover and rethink how these designer coordination polymers will influence the realm of materials science. This book opens with a look at a deeply controversial issue, MOF stability, which has plagued many systems, but ultimately has led to better materials that proved to be more robust allowing them to be investigated for multiple applications. This book successfully highlights many of these useful applications that MOFs are well adapted for. Because MOF components, inorganic and organic, can combine the best of both chemical domains, MOFs will improve our environment by removing harmful contaminants from the air and water, reduce the energy required to perform chemical reactions, partition hard to separate molecular mixtures, and form the next-generation of magnetic and electronic materials. MOFs will eventually be used for everyday activities — for monitoring or reacting to changing conditions. Readers of this book can then take note and implement MOFs in their line of research.
Author: Lida Hashemi
Publisher: John Wiley & Sons
ISBN: 1119460247
Category : Science
Languages : en
Pages : 378
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Book Description
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.
