Metal-Organic Frameworks
Wiley-VCH (Verlag)
978-3-527-32870-3 (ISBN)
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An international and interdisciplinary team of leading experts from both academia and industry report on the wide range of hot applications for MOFs, discussing both the advantages and limits of the material. The resulting overview covers everything from catalysis, H2 and CH4 storage and gas purification to drug delivery and sensors.From the Contents:- Design of Porous Coordination Polymers/Metal-Organic Frameworks: Past, Present and Future- Design of Functional Metal-Organic Frameworks by Post-Synthetic Modification- Thermodynamic Methods for Prediction of Gas Separation in Flexible Frameworks- Separation and purification of gases by MOFs- Opportunities for MOFs in CO2 capture from flue gases, natural gas and syngas by adsorption- Manufacture of MOF thin films on structured supports for separation and catalysis- Research status of Metal-Organic Frameworks for on-board cryo-adsorptive hydrogen storage applications- Separation of xylene isomers- Metal-Organic Frameworks as Catalysts for Organic Reactions- Biomedical applications of Metal Organic Frameworks- Metal Organic Frameworks for Biomedical Imaging- Luminescent Metal-Organic Frameworks- Deposition of thin films for sensor applications- Industrial MOF Synthesis- MOF shaping and immobilisationA must-have for every scientist in the field.
David Farrusseng received his BSc in chemistry from the University of Montpellier (France) under the supervision of Prof. R. Corriu. In 1999, he got his PhD in Materials Science at the European Institute of Membranes in Montpellier under the guidance of Drs. A. Julbe and C. Guizard. He joined as post-doc the group of Prof. F. Schüth at the MPI für Kohlenforschung (Germany). In 2001, he was appointed CNRS researcher at IRCELYON in the group of Dr. C. Mirodatos. He is currently group leader at IRCELYON. His research activities focus on the design of materials for original catalytic and separation processes and on the development of high-throughput approaches for which he was awarded in 2008 by the French Chemical Society. He is author of approximately 90 peer-reviewed publications and 15 patents.
Preface
PART I: Design of Multifunctional Porous MOFs
DESIGN OF POROUS COORDINATION POLYMER/METAL-ORGANIC FRAMEWORKS: PAST, PRESENT AND FUTURE
Introduction
Background and Ongoing Chemistry of Porous Coordination Polymers
Multifunctional Frameworks
Preparation of Multifunctional Frameworks
Perspectives
DESIGN OF FUNCTIONAL METAL-ORGANIC FRAMEWORKS BY POST-SYNTHETIC MODIFICATION
Building a MOFs Toolbox by Post-Synthetic Modification
Post-Functionalization of MOFs by Host-Guest Interactions
Post-Functionalization of MOFs Based on Coordination Chemistry
Post-Functionalization of MOFs by Covalent Bonds
Tandem Post-Modification for the Immobilization of Organometallic Catalysts
Critical Assessment
Conclusion
PART II: Gas Storage and Separation Applications
THERMODYNAMIC METHODS FOR PREDICTION OF GAS SEPARATION IN FLEXIBLE FRAMEWORKS
Introduction
Theoretical Background
Molecular Simulation Methods
Analytical Methods Based on Experimental Data
Outlook
SEPARATION AND PURIFICATION OF GASES BY MOFS
Introduction
General Principles of Gas Separation and Purification
MOFs for Separation and Purification Processes
Conclusions and Perspectives
OPPORTUNITIES FOR MOFS IN CO2 CAPTURE FROM FLUE GASES, NATURAL GAS, AND SYNGAS BY ADSORPTION
Introduction
General Introduction to Pressure Swing Adsorption
Production of H2 from Syngas
CO2 Removal from Natural Gas
Post-Combustion CO2 Capture
MOFs
Conclusions
MANUFACTURE OF MOF THIN FILMS ON STRUCTURED SUPPORTS FOR SEPARATION AND CATALYSIS
Advantages and Limitations of Membrane Technologies for Gas and Liquid Separation
Mechanisms of Mass Transport and Separation
Synthesis of Molecular Sieve Membranes
Application of MOF Membranes
Limitations
Conclusions and Outlook
RESEARCH STATUS OF METAL-ORGANIC FRAMEWORKS FOR ON-BOARD CRYO-ADSORPTIVE HYDROGEN STORAGE APPLICATIONS
Introduction - Research Problem and Significance
MOFs as Adsorptive Hydrogen Storage Options
Experimental Techniques and Methods for Performance and Thermodynamic Assessment of Porous MOFs for Hydrogen Storage
Material Research Results
From Laboratory-Scale Materials to Engineering
Conclusion
PART III: Bulk Chemistry Applications
SEPARATION OF XYLENE ISOMERS
Xylene Separation: Industrial Processes, Adsorbents, and Separation Principles
Properties of MOFs Versus Zeolites in Xylene Separations
Separation of Xylenes Using MIL-47 and MIL-53
Conclusions
METAL-ORGANIC FRAMEWORKS AS CATALYSTS FOR ORGANIC REACTIONS
Introduction
MOFs with Catalytically Active Metal Nodes in the Framework
Catalytic Functionalization of Organic Framework Linkers
Homochiral MOFs
MOF-Encapsulated Catalytically Active Guests
Mesoporous MOFs
Conclusions
PART IV: Medical Applications
BIOMEDICAL APPLICATIONS OF METAL-ORGANIC FRAMEWORKS
Introduction
MOFs for Bioapplications
Therapeutics
Diagnostics
From Synthesis of Nanoparticles to Surface Modification and Shaping
Discussion and Conclusion
METAL-ORGANIC FRAMEWORKS FOR BIOMEDICAL IMAGING
Introduction
Gadolinium Carboxylate NMOFs
Manganese Carboxylate NMOFs
Iron Carboxylate NMOFs: The MIL Family
Iodinated NMOFs: CT Contrast Agents
Lanthanide Nucleotide NMOFs
Guest Encapsulation within NMOFs
Conclusion
PART V: Physical Applications
LUMINESCENT METAL-ORGANIC FRAMEWORKS
Introduction
Luminescence Theory
Ligand-Based Luminescence
Metal-Based Luminescence
Guest-Induced Luminescence
Applications of Luminescent MOFs
Conclusion
DEPOSITION OF THIN FILMS FOR SENSOR APPLICATIONS
Introduction
Literature Survey
Signal Transduction Modes
Considerations in Selecting MOFs for Sensing Applications
MOF Thin Film Growth: Methods, Mechanisms, and Limitations
Conclusions and Perspectives
PART VI: Large-Scale Synthesis and Shaping of MOFs
INDUSTRIAL MOF SYNTHESIS
Introduction
Raw Materials
Synthesis
Shaping
Applications
Conclusion and Outlook
MOF SHAPING AND IMMOBILISATION
Introduction
MOF@Fiber Composite Materials
Requirements of Adsorbents for Individual Protection
MOFs in Monolithic Structures
Erscheint lt. Verlag | 27.7.2011 |
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Verlagsort | Weinheim |
Sprache | englisch |
Maße | 170 x 240 mm |
Gewicht | 935 g |
Themenwelt | Naturwissenschaften ► Chemie ► Anorganische Chemie |
Technik ► Maschinenbau | |
Schlagworte | Anorganische Chemie • Brennstoffzellen • catalysis • chemical engineering • Chemie • Chemische Verfahrenstechnik • Chemistry • Energie • Energy • Hydrogen, Batteries & Fuel Cells • Hydrogen, Batteries & Fuel Cells • Inorganic Chemistry • Katalyse • Metallorganische Verbindungen • MOF • Nanomaterialien • nanomaterials • Nanotechnologie • nanotechnology • Separations • Stofftrennverfahren • Wasserstoff, Batterien u. Brennstoffzellen |
ISBN-10 | 3-527-32870-X / 352732870X |
ISBN-13 | 978-3-527-32870-3 / 9783527328703 |
Zustand | Neuware |
Informationen gemäß Produktsicherheitsverordnung (GPSR) | |
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