Description
Metal-Organic Framework-Based Nanomaterials for Energy Conversion and Storage addresses current challenges and covers design and fabrication approaches for nanomaterials based on metal organic frameworks for energy generation and storage technologies. The effect of synthetic diversity, functionalization, ways of improving conductivity and electronic transportation, tuning-in porosity to accommodate various types of electrolyte, and the criteria to achieve the appropriate pore size, shape and surface group of different metal sites and ligands are explored. The effect of integration of other elements, such as second metals or hetero-atomic doping in the system, to improve catalytic activity and durability, are also covered.This is an important reference source for materials scientists, engineers and energy scientists looking to further their understanding on how metal organic framework-based nanomaterials are being used to create more efficient energy conversion and storage systems.- Describes major metal organic framework-based nanomaterials applications for fuel cell, battery, supercapacitor and photovoltaic applications- Provides information on the various nanomaterial types used for creating the most efficient energy conversion and storage systems- Assesses the major challenges of using nanotechnology to manufacture energy conversion and storage systems on an industrial scale
Table of Contents
Part I: Fundamentals1. MOF-based nanostructures and nanomaterials for next-generationenergy storage: an introduction2. Recent advances in MOFs for electrochemical energy storageand conversion devices3. Design and construction of MOF nanomaterials4. Strategies to enhance the electrochemical properties of MOFs5. Biological MOFs (bio-MOFs) for energy applicationsPart II: Metal-Organic frameworks for fuel cells6. MOF-based electrocatalysts for oxygen evolution reactions7. Recent development in MOFs for oxygen evolution reactions8. Effect of structural modifications on the oxygen reduction reaction properties of metal-organic framework-based catalysts9. Metal organic framework-based nanomaterials as suitable electrocatalysts for evolution of hydrogenPart III: Metal-organic frameworks for batteries10. MOF nanomaterials for battery cathodes11. MOFs and their derivatives for anode of high-performancerechargeable batteries12. Polyoxometalate-based metal organic frameworks (POMOFs)for lithium-ion batteries13. MOFs-based nanomaterials for metal-sulfur batteries14. MOFs-based nanomaterials for metal-ion batteries15. MOF-based nanomaterials for zinc-based battery cathodes16. MOF-based electrolytes for battery applicationsPart IV: Metal-organic frameworks for supercapacitors17. Recent development in MOFs for supercapacitor applications18. MOFsemetal oxides/sulfides/phoshides nanocomposites for supercapacitors19. MOFs-carbon nanocomposites for supercapacitors20. Flexible supercapacitors based on nanocomposites of MOFs21. Other nanocomposites of MOFs for supercapacitorsPart V: Metal-organic frameworks for photovoltaics22. MOFs-based dye-sensitized photovoltaics23. Recent development in MOFs for perovskite-based solar cells24. Integrating MOFs into dye-sensitized solar cells25. Integrating MOFs into dye-sensitized solar cellsPart VI: Metal-organic frameworks for fuel/gas storage26. MOFs for hydrogen storage27. Multicriteria decision making in organic-metal frameworks for fuel storage28. Current development in MOFs for hydrogen storage: a mechanistic investigation29. MOFs for solar photochemistry applicationsPart VII: Metal-organic franeworks for other applications30. Metal-organic frameworks for nanogenerators31. MOF-based photocatalysts for hydrogen generation by water splitting32. Metal-organic framework for photocatalytic reduction of carbon dioxide33. MOF-based advanced nanomaterials for electrocatalysisapplications
