Note: Intro -- Contents -- 1 Biomass-Derived Polyurethanes for Sustainable Future -- Abstract -- 1 Introduction -- 1.1 Chemicals for Preparation of Polyurethanes -- 1.2 Importance of Green Chemicals and Synthesis Methods -- 1.3 Characteristics of Biomaterials for Polyurethanes -- 2 Bio-Oils as a Renewable Resource for Polyurethanes -- 2.1 Epoxidation and Ring-Opening Reactions -- 2.2 Hydroformation and Hydrogenation Reactions -- 2.3 Ozonolysis -- 2.4 Thiol-Ene Reaction -- 2.5 Transesterification Reaction -- 3 Terpenes as Green Starting Chemicals for Polyurethanes -- 4 Lignin for Green Polymers -- 5 Conclusion -- References -- 2 Mechanochemistry: A Power Tool for Green Synthesis -- Abstract -- 1 Introduction -- 2 History of Mechanochemistry -- 3 Principles of Mechanochemistry -- 3.1 Mechanisms and Kinetics of Mechanochemistry -- 3.2 Effects of Reaction Parameters -- 4 Mechanochemical Synthesis of Materials -- 4.1 Mechanochemical Synthesis of Co-crystals -- 4.2 Mechanochemistry in Inorganic Synthesis -- 4.3 Mechanochemistry in Organic Synthesis -- 4.4 Mechanochemistry in Metal-Organic Frameworks (MOFs) -- 4.5 Mechanochemistry in Porous Organic Materials (POMs) -- 4.6 Mechanochemical Synthesis of Polymers -- 5 Conclusions -- References -- 3 Future Trends in Green Synthesis -- Abstract -- 1 Introduction -- 2 Green Chemistry Metrics -- 2.1 Atom Economy (AE) -- 2.2 Environmental Factor (E Factor) -- 2.3 Process Mass Intensity (PMI) -- 2.4 Reaction Mass Efficiency (RME) -- 3 Application of Green Concept in Synthesis -- 3.1 Solvent-Based Organic Synthesis -- 3.2 Aqueous Medium -- 3.2.1 Micellar Media -- 3.2.2 Different Non-Aqueous Media -- Ionic Liquids -- Fluorous Media -- Supercritical Fluid -- Solvent-Free Synthesis -- 4 Future Trends -- References -- 4 Plant-Mediated Green Synthesis of Nanoparticles -- Abstract -- 1 Introduction. , 2 Methods for Metallic Nanoparticle Biosynthesis -- 3 Green Biosynthesis of Metallic NPs -- 3.1 Gold Nanoparticles -- 3.2 Platinum Nanoparticles -- 3.3 Silver Nanoparticles -- 3.4 Zinc Oxide Nanoparticles -- 3.5 Titanium Dioxide Nanoparticles -- 4 Different Parts Used for the Synthesis of Metallic Nanoparticles -- 4.1 Fruit -- 4.2 Stem -- 4.3 Seeds -- 4.4 Flowers -- 4.5 Leaves -- 5 Conclusions -- References -- 5 Green Synthesis of Hierarchically Structured Metal and Metal Oxide Nanomaterials -- Abstract -- 1 Introduction -- 2 Advantages of Green Synthesis Methods -- 3 Green Synthesis Methods for Hierarchically Structured Metal and Metal Oxide Nanomaterials -- 3.1 Biological Methods -- 3.1.1 Using Microorganism -- Microorganisms as Reactant -- Microorganism as Template -- 3.1.2 Using Plant -- Plant as Reactant -- Plant as Template -- 3.1.3 Using Other Green Templates -- 3.2 Physical and Chemical Methods -- 3.2.1 Green Techniques -- 3.2.2 Green Reagents -- 3.2.3 Green Solvents -- 4 Growth Mechanism of Metal and Metal Oxide HSNs -- 4.1 Biological Method -- 4.1.1 Biomolecules as Reagents -- 4.1.2 Biomolecules as Templates -- 4.2 Physical and Chemical Methods -- 5 Applications of Hierarchically Structured Metal and Metal Oxide Nanomaterials -- 5.1 Biomedical Application -- 5.2 Environmental Remediation -- 5.2.1 Wastewater Treatment -- 5.2.2 Energy Storage -- 5.2.3 Sensing -- 6 Present Challenges and Future Prospect -- Acknowledgements -- References -- 6 Bioprivileged Molecules -- Abstract -- 1 Introduction -- 2 Four Carbon 1,4-Diacids -- 2.1 Succinic Acid -- 2.2 Fumaric Acid -- 2.3 Malic Acid -- 3 Furan 2,5-Dicarboxylic Acid (FDCA) -- 4 3-Hydroxypropionic Acid (3-HPA) -- 5 Glucaric Acid -- 6 Glycerol -- 7 Aspartic Acid -- 8 Itaconic Acid -- 9 3-Hydroxybutyrolactone -- 10 Sorbitol -- 11 Xylitol -- 12 Glutamic Acid -- 13 Levulinic Acid. , 14 Emerging Molecules -- 15 Conclusion -- References -- 7 Membrane Reactors for Green Synthesis -- Abstract -- 1 Introduction -- 2 Chemical Reaction Enzymatic MR Using Supercritical CO2-IL -- 2.1 Ionic Liquid Media Effect on Free CLAB -- 2.2 Butyl Propionate Synthesis Using Active Membranes SC-CO2 and SC-CO2/IL -- 2.3 Butyl Propionate Synthesis Using Active Membranes in Hexane/IL -- 3 Mixed Ionic Electronic MR -- 3.1 Methane Flow Rate and Concentration Effects on Side II of Membrane -- 3.2 Steam Flow Effect on Side I of Membrane -- 3.3 Temperature Effect -- 4 Green Synthesis of Methanol in a Membrane Reactor -- 5 Green Fuel Energy -- 5.1 Green H2 Energy -- 5.2 Biofuel Energy -- 5.3 Green Fuel Additive -- 6 Biocatalyst Membrane Reactors -- 7 Photocatalytic Membrane Reactors -- 8 Conclusions -- References -- 8 Application of Membrane in Reaction Engineering for Green Synthesis -- Abstract -- 1 Introduction -- 2 Applications of Membrane Reactors in Reaction Engineering -- 2.1 Syngas Production -- 2.2 Hydrogen Production -- 2.3 CO2 Thermal Decomposition -- 2.4 Higher Hydrocarbon Production -- 2.5 Methane Production -- 2.6 Ammonia Production -- 3 Environmental Impacts -- 4 Conclusions and Future Recommendations -- Acknowledgements -- References -- 9 Photo-Enzymatic Green Synthesis: The Potential of Combining Photo-Catalysis and Enzymes -- Abstract -- 1 Introduction -- 2 Principle -- 3 Enzymes Involved in Light-Driven Catalysis -- 3.1 Heme-Containing Enzymes -- 3.1.1 Cytochrome P450 -- 3.1.2 Peroxidases -- 3.2 Flavin-Based Enzyme -- 3.2.1 Baeyer-Villiger Monooxygenases -- 3.2.2 Old Yellow Enzymes -- 3.3 Metal Cluster-Centered Enzyme -- 3.3.1 Hydrogenases -- 3.3.2 Carbon Monoxide Dehydrogenases -- 4 Nanoparticle-Based Activation of Enzyme -- 5 Applications in Photo-Biocatalysis -- 5.1 Isolated Enzymes/Cell Lysates -- 6 Summary and Future Scope -- References. , 10 Biomass-Derived Carbons and Their Energy Applications -- Abstract -- 1 Introduction -- 2 Types of Biomass Materials -- 2.1 Plant-Based Carbons -- 2.2 Fruit-Based Carbons -- 2.3 Animal-Based Carbons -- 2.4 Microorganism-Based Carbons -- 3 Activation of Biomass-Derived Carbons -- 3.1 Activation of Carbons -- 3.1.1 Chemical Activation of Carbons -- 3.1.2 Carbon Activation Through Physical Method -- 3.1.3 Self-activation of Carbons -- 3.2 Pyrolysis Techniques -- 3.2.1 Effect of Temperature -- 3.2.2 Effect of Residence Time -- 3.2.3 Heating Rate Effect -- 3.2.4 Size of the Particle -- 3.3 Microwave-Assisted Technique -- 3.4 Carbonization by Hydrothermal -- 3.5 Ionothermal Carbonization -- 3.6 Template Method -- 4 Energy Storage Applications of Biomass Carbons -- 4.1 Supercapacitors -- 4.2 Li/Na-Ion Batteries -- 5 Conclusion -- Acknowledgements -- References -- 11 Green Synthesis of Nanomaterials via Electrochemical Method -- Abstract -- 1 Introduction -- 2 Green Synthesis -- 2.1 Application of Biology in Green Synthesis -- 2.2 Green Synthesis Based on the Application of Solvent -- 3 Computational Data and Analysis -- 4 Electrochemical Method -- 5 Electrodeposition Method -- 5.1 Experimental Setup for Electrodeposition -- 6 Research Work: Using Green Electrochemical Methods for Nanomaterials Synthesis -- 7 Conclusion -- References -- 12 Microwave-Irradiated Synthesis of Imidazo[1,2-a]pyridine Class of Bio-heterocycles: Green Avenues and Sustainable Developments -- Abstract -- 1 Introduction -- 2 Microwave-Assisted Synthesis of 2-arylimidazo[1,2-a]pyridines [Abbreviated as 2-Aryl-IPs]. -- 2.1 Synthesis of Fused Bicyclic Heteroaryl Boronates and Imidazopyridine-Quinazoline Hybrids Under MW-irradiations -- 2.2 MW-Irradiated Synthesis of IPs Using Multi-Component Strategy Under Neat Conditions. , 2.3 One-Pot, Three-Component Synthesis of 2-Phenyl-H-Imidazo[1,2-α]pyridine Under MW-Irradiations -- 2.4 Microwave-Assisted Amine-Triggered Benzannulation Strategy for the Preparation of 2,8-Diaryl-6-Aminoimidazo-[1,2-a]pyridines -- 2.5 MW-Assisted NaHCO3-catalyzed Synthesis of Imidazo[1,2-a]pyridines in PEG400 Media and Its Practical Application in the Synthesis of 2,3-Diaryl-IP Class of Bio-Heterocycles -- 2.6 MW-Irradiated, Ligand-Free, Palladium-Catalyzed, One-Pot 3-component Reaction for an Efficient Preparation of 2,3-Diarylimidazo[1,2-a]pyridines -- 2.7 MW-Assisted Water-PEG400-mediated Synthesis of 2-Phenyl-IP via Multi-Component Reaction (MCR) -- 2.8 Microwave-Irradiated Synthesis of Imidazo[1,2-a]pyridines Under Neat, Catalyst-Free Conditions -- 2.9 Green Synthesis of Imidazo[1,2-a]pyridines in H2O -- 2.10 Microwave-Assisted Neat Synthesis of Substituted 2-Arylimidazo[1,2-a]Pyridines -- 2.11 Microwave-Assisted Nano SiO2 Neat Synthesis of Substituted 2-Arylimidazo[1,2-a]pyridines -- 2.12 Microwave-Assisted NaHCO3-Catalyzed Synthesis of 2-phenyl-IPs -- 3 Microwave-Assisted Synthesis of 3-amino-2-arylimidazo[1,2-a]pyridines [3-amino-2-aryl-IPs] -- 3.1 Microwave-Irradiated Synthesis of 3-aminoimidazo[1,2-a]pyridines via Fluorous Multi-component Pathway -- 3.2 MW-Irradiated Synthetic Protocol for 3-aminoimidazo[1,2-a]pyridines via MCR Pathway -- 3.3 MW-Assisted Sequential Ugi/Strecker Reactions Involving 3-Center-4-Component and 3-Center-5-Component MCR Strategy -- 3.4 One-Pot, 4-component Cyclization/Suzuki Coupling Leading to the Rapid Formation of 2,6-Disubstituted-3-Amino-IPs Under Microwave Irradiations -- 3.5 ZnCl2-catalyzed MCR of 3-aminoimidazo[1,2-a]pyridines Using MW Conditions -- 3.6 Microwave-Promoted Preparation of N-(3-arylmethyl-2-oxo-2,3-dihydroimidazo[1,2-a]pyridin-3-Yl)Benzamides. , 3.7 MW-Assisted Multi-component Neat Synthesis of Benzimidazolyl-Imidazo[1,2-a]pyridines.

Note: Front Cover -- Metal-Organic Frameworks for Chemical Reactions -- Copyright Page -- Contents -- List of contributors -- 1 Metal-organic frameworks and their composites -- 1.1 Introduction -- 1.2 Metal-organic framework composites -- 1.2.1 Processing of metal-organic framework composites -- 1.2.2 Types of metal-organic framework composites -- 1.2.2.1 Metal-organic framework-polymer composites -- 1.2.2.2 Metal-organic framework-quantum dot composites -- 1.2.2.3 Metal-organic framework-metal nanoparticle composites -- 1.2.2.4 Metal-organic framework-graphene oxide composites -- 1.2.2.5 Metal-organic framework-polyoxometalate composites -- 1.2.2.6 Metal-organic framework-enzyme composites -- 1.2.2.7 Metal-organic framework-cellulose composites -- 1.2.2.8 Metal-organic framework-silica composites -- 1.2.2.9 Metal-organic framework-activated carbon composites -- 1.2.2.10 Metal-organic framework-aluminum composites -- 1.2.2.11 Metal-organic framework-molecular species composites -- 1.2.2.12 Metal-organic framework-hybrid composites -- 1.3 Characterization of metal-organic framework composites -- 1.3.1 X-ray diffraction analysis -- 1.3.2 X-ray photoelectron spectroscopy -- 1.3.3 Fourier-transform infrared spectroscopy -- 1.3.4 Scanning electron microscopy analysis -- 1.4 Conclusion -- References -- 2 Metal-organic framework for batteries and supercapacitors -- 2.1 Introduction -- 2.2 Metal-organic frameworks -- 2.3 Metal-organic frameworks for batteries -- 2.3.1 Lithium-ion batteries -- 2.3.2 Sodium-ion batteries -- 2.3.3 Li-O2 batteries -- 2.3.4 Li-S batteries -- 2.4 Metal-organic frameworks for supercapacitors -- 2.4.1 Metallic oxides/sulfides for supercapacitors -- 2.4.2 Carbon for supercapacitors -- 2.5 Conclusion -- References -- 3 Titanium-based metal-organic frameworks for photocatalytic applications -- 3.1 Introduction -- 3.1.1 The Ti-chemistry. , 3.2 Preparation of titanium-based metal-organic frameworks and the selection of precursors -- 3.2.1 Direct synthesis -- 3.2.2 Solvothermal synthesis -- 3.2.3 Ultrasonic and microwave-assisted synthesis -- 3.2.4 The method of coordination-covalent combination -- 3.2.5 Method of postsynthetic cation exchange -- 3.2.6 Vapor-assisted crystallization method -- 3.2.7 Synthesis of titanium-based metal-organic framework composites -- 3.3 The structure of titanium-based metal-organic frameworks -- 3.3.1 Photocatalytic application of titanium-based metal-organic frameworks -- 3.4 Photocatalytic oxidation reaction -- 3.4.1 Titanium-based metal-organic framework composites -- 3.4.2 Photocatalytic NO oxidation and antibacterial activity -- 3.4.3 Photocatalytic CO2 reduction -- 3.4.4 Photocatalytic H2 generation from water splitting -- 3.4.5 Photocatalytic degradation of organic pollutants -- 3.4.6 Photocatalytic polymerization -- 3.4.7 Photocatalytic deoximation reaction -- 3.4.8 Photocatalytic sensors -- 3.5 Conclusion -- References -- 4 Electrochemical aspects of metal-organic frameworks -- 4.1 Introduction -- 4.2 Electrochemical synthesis of metal-organic frameworks -- 4.2.1 Direct electrosynthesis of metal-organic frameworks -- 4.2.1.1 Anodic dissolution -- 4.2.1.2 Reductive deprotonation -- 4.2.2 Indirect electrosynthesis of metal-organic frameworks -- 4.2.2.1 Anchoring of a linker -- 4.2.2.2 Galvanic displacement -- 4.2.2.3 Electrophoretic deposition -- 4.2.2.4 Self-templated synthesis from metal oxide/hydroxide nanostructures -- 4.3 Electrochemical applications of metal-organic frameworks -- 4.3.1 Battery applications of various metal-organic frameworks -- 4.3.1.1 Metal-organic frameworks for Li-ion batteries -- 4.3.1.2 Metal-organic frameworks for Li-S batteries and other batteries -- 4.3.2 Supercapacitors applications of various metal-organic frameworks. , 4.3.3 Electrocatalysis applications of various metal-organic frameworks -- 4.3.4 Electrochemical sensing applications of various metal-organic frameworks -- 4.3.5 Other electrochemical applications of metal-organic frameworks -- 4.4 Conclusion -- Acknowledgment -- References -- 5 Permeable metal-organic frameworks for fuel (gas) storage applications -- 5.1 Introduction -- 5.2 Concept of porosity in fuel storage -- 5.3 Permeable metal-organic frameworks for H2 storage application -- 5.4 Permeable metal-organic frameworks for CH4 storage applications -- 5.5 Permeable metal-organic frameworks for C2H2 storage applications -- 5.6 Permeable metal-organic frameworks for CO2 storage applications -- 5.7 Conclusion -- Acknowledgment -- References -- 6 Excessively paramagnetic metal organic framework nanocomposites -- 6.1 Introduction -- 6.2 Discussion and applications -- 6.3 Conclusion -- References -- 7 Expanding energy prospects of metal-organic frameworks -- 7.1 Introduction -- 7.2 Metal-organic frameworks in Li-ion batteries -- 7.3 Applications of metal-organic frameworks as electrode material for lithium-ion batteries -- 7.4 Applications of high conductive metal-organic frameworks -- 7.5 Utilization of metal-organic frameworks as electric double-layer capacitors (supercapacitors) -- 7.5.1 Applications of optimizing the surface area -- 7.6 Utilization of lithium-oxygen as separators -- 7.7 Utilization of solid-state electrolytes -- 7.8 Applications of electrode-electrolyte alliances -- 7.9 Fuel cell applications -- 7.10 Electrocatalytic applications -- 7.11 Conclusion -- References -- 8 Metal-organic framework-based materials and renewable energy -- 8.1 Introduction -- 8.2 0D-metal-organic framework-based materials-nanoparticles -- 8.2.1 Multishell 0D-metal-organic framework-based materials-nanoparticles. , 8.2.2 Hollow 0D-metal-organic framework-based materials-nanoparticles -- 8.3 1D-metal-organic framework-based materials-nanoparticles -- 8.3.1 Nanotube 1D-metal-organic framework-based materials-nanoparticles -- 8.3.2 Nanorod 1D-metal-organic framework-based materials-nanoparticles -- 8.3.3 Nanowire 1D-metal-organic framework-based materials-nanoparticles -- 8.4 2D-metal-organic framework-based materials-nanoparticles -- 8.4.1 Nanosheet 2D-metal-organic framework-based materials-nanoparticles -- 8.4.2 Holey 2D-metal-organic framework-based materials-nanoparticles -- 8.5 3D-metal-organic framework-based materials-nanoparticles -- 8.5.1 Array 3D-metal-organic framework-based materials-nanoparticles -- 8.5.2 Hierarchical 3D-metal-organic framework-based materials-nanoparticles -- 8.5.3 Superstructured 3D-metal-organic framework-based materials-nanoparticles -- 8.6 Conclusion -- Acknowledgments -- References -- 9 Applications of metal-organic frameworks in analytical chemistry -- 9.1 Introduction -- 9.2 Desirable characteristics of MOFs for analytical chemistry applications -- 9.3 Recent applications -- 9.3.1 Recent applications in sample preparation -- 9.3.1.1 Solid-phase extraction -- 9.3.1.2 Dispersive solid-phase extraction -- 9.3.1.3 Solid-phase microextraction -- 9.3.1.4 Matrix solid-phase dispersion -- 9.3.1.5 Stir bar sorptive extraction -- 9.3.2 Recent applications in chromatography -- 9.3.2.1 Gas chromatography -- 9.3.2.2 Liquid chromatography -- 9.3.2.3 Electrophoretic separations -- 9.3.3 Recent applications in sensor development -- 9.3.3.1 Electrochemical sensors -- 9.3.4 Electroluminescent/optical sensors -- 9.4 Conclusion and future remarks -- Acknowledgement -- References -- 10 Modified metal-organic frameworks as photocatalysts -- 10.1 Introduction -- 10.2 Structure, merits, and strategies -- 10.3 Metal-organic framework modification. , 10.3.1 Ligands and clusters -- 10.3.2 Metals -- 10.3.3 Semiconductors -- 10.3.4 Dyes -- 10.3.5 Composites/hybrids -- 10.4 Applications -- 10.4.1 Hydrogen production -- 10.4.2 Water splitting -- 10.4.3 Other applications -- 10.5 Conclusion and outlook -- Acknowledgments -- Abbreviations -- References -- 11 The sensing applications of metal-organic frameworks and their basic features affecting the fate of detection -- 11.1 Introduction -- 11.2 Type of metal-organic frameworks -- 11.2.1 MOF-5 -- 11.2.2 HKUST-1 -- 11.2.3 UiO -- 11.2.4 ZIF-8 and ZIF-67 -- 11.2.5 MOF-76 -- 11.2.6 MIL-101 -- 11.3 Pore diameter -- 11.4 Pore morphology -- 11.5 Combination with different nanoparticles -- 11.6 The sensing applications carried out with metal-organic frameworks -- 11.6.1 Gas-sensing applications -- 11.6.2 Metal ion sensing applications -- 11.6.3 Hydrophobic molecule sensing applications -- 11.7 Conclusion -- References -- 12 Thermomechanical and anticorrosion characteristics of metal-organic frameworks -- 12.1 Introduction -- 12.2 Design of metal-organic frameworks -- 12.2.1 Key structures in metal-organic frameworks -- 12.2.2 Dimensionality of metal-organic frameworks -- 12.2.3 Methods for the construction of metal-organic framework structures -- 12.2.3.1 Hydro(solvo)thermal method -- 12.2.3.2 Microwave and ultrasonic methods -- 12.2.3.3 Electrochemical production -- 12.2.3.4 Diffusion method -- 12.2.3.5 Mechanochemical synthesis -- 12.2.3.6 Solvent evaporation and isothermal synthesis -- 12.3 Stability of metal-organic frameworks -- 12.3.1 Various aspects regarding the stability of metal-organic frameworks -- 12.3.1.1 Thermal stability of metal-organic frameworks -- 12.3.1.2 Mechanical stability -- 12.3.1.3 Chemical stability -- 12.3.1.4 Water stability -- 12.4 Application -- 12.4.1 Anticorrosion properties of metal-organic frameworks. , 12.4.1.1 Metal-organic frameworks as a corrosion inhibitors.

Note: Intro -- Contents -- 1 Chemical Valorization of CO2 -- Abstract -- 1 Introduction -- 2 CO2-Derived Fuels and Chemicals -- 2.1 Methane -- 2.2 Methanol -- 2.3 Dimethyl Ether -- 2.4 Formic Acid -- 2.5 Ethanol -- 2.6 CO2-Fischer-Tropsch Liquid Fuels -- 2.7 Carbon Monoxide-Syngas -- 3 CO2 Chemically Derived Materials -- 3.1 Polymers -- 3.2 CO2-Derived Building Materials -- 4 Conclusions -- References -- 2 Progress in Catalysts for CO2 Reforming -- Abstract -- 1 Introduction -- 2 Technologies for Capturing and Storing Carbon Dioxide -- 3 Technologies for Using Carbon Dioxide -- 4 Methane Dry Reforming Process -- 4.1 Progress in Catalysts for Methane Dry Reforming (1928-1989) -- 4.2 Progress in Catalysts for Methane Dry Reforming (1990-1999) -- 4.3 Progress in Catalysts for Methane Dry Reforming (2000-2009) -- 4.4 Progress in Catalysts for Methane Dry Reforming (2010-2019) -- 4.5 Current Status in the Catalysts for Methane Dry Reforming -- 5 Dry Reforming of Other Compounds -- 6 Use of Steam or Oxygen in Dry Reforming of Methane and Other Compounds -- 7 Solid Oxide Fuel Cells Fueled with Biogas -- 8 Commercialization of Dry Reforming Process -- 9 Conclusions -- References -- 3 Fuel Generation from CO2 -- Abstract -- 1 Introduction -- 2 Approaches for Directly Converting CO2 to Fuels -- 2.1 Pure CO2 Decomposition Technology -- 2.2 Reagent-Based CO2 Conversion Technology -- 2.2.1 Dry Deformation of Methane Technology -- 2.2.2 Catalytic Hydrogenation of CO2 -- 3 Biological CO2 Fixation for Fuels -- 3.1 Thermochemical Conversion -- 3.1.1 Torrefaction -- 3.1.2 Pyrolysis -- 3.1.3 Thermochemical Liquefaction -- 3.1.4 Gasification -- 3.1.5 Direct Combustion -- 3.2 Biochemical Conversion -- 3.2.1 Biodiesel -- 3.2.2 Bioethanol -- 3.2.3 Biomethane -- 3.2.4 Biohydrogen -- 3.2.5 Bioelectricity -- 3.2.6 Volatile Organic Compounds. , 4 Conclusion and Future Perspectives -- References -- 4 Thermodynamics of CO2 Conversion -- Abstract -- 1 Introduction -- 2 Carbon Dioxide Capture -- 3 Carbon Dioxide Utilisations -- 4 Thermodynamic Considerations -- 5 Thermodynamics of CO2 -- 5.1 The Thermodynamic Attainable Region (AR) -- 5.2 Using Hess's Law to Transform the Extents to G-H AR @ 25˚C -- 5.3 Increasing Temperature on G-H AR -- 6 Conclusion -- Acknowledgements -- References -- 5 Enzymatic CO2 Conversion -- Abstract -- 1 Introduction -- 1.1 CO2 as a Greenhouse Gas -- 1.2 Carbon Capture, Storage, and Utilization -- 1.3 CO2 as a Chemical Feedstock -- 1.4 CO2 Conversion with Enzymes -- 2 Natural Conversion of CO2 in Cells -- 3 Enzymatic Conversion of CO2 in Cells -- 3.1 Conversion of CO2 by a Single Enzyme (in vitro) -- 3.1.1 Formate Dehydrogenase -- 3.1.2 Carbonic Anhydrase -- 3.1.3 Carbon Monoxide Dehydrogenase -- 3.1.4 Ribulose-1,5-bisphosphate Carboxylase/Oxygenase (RuBisCO) -- 3.2 Conversion of CO2 by a Multi-Enzyme Cascade in vitro -- 3.3 Other Ways (Photocatalytic CO2 Methanation) -- 4 Industrial Applications -- 4.1 Alcohols -- 4.2 Organic Acids -- 4.3 Terpenoids -- 4.4 Fatty Acids -- 4.5 Polyhydroxyalkanoates -- 4.6 Calcium Carbonate -- 5 Summary and Future Prospects -- References -- 6 Electrochemical CO2 Conversion -- Abstract -- 1 Introduction -- 2 Electrochemical CO2 Conversion -- 2.1 Fundamentals of the Process -- 2.2 Variants of Electrochemical Conversion of CO2 -- 2.2.1 Aqueous Electrolytes -- 2.2.2 Non-Aqueous Electrolytes -- 2.2.3 Solid Oxide Electrolytes -- 2.2.4 Molten Salt Electrolytes -- 3 Electrochemical CO2 Conversion from Molten Salts -- 3.1 Present State of Electrochemical Reduction of CO2in Molten Salts for the Production of Solid-Phase Carbonaceous Nanomaterials -- 3.2 Direct Electrochemical Reduction of CO2 in Chloride Melts. , 3.3 Indirect Electrochemical Reduction of CO2 in Molten Salts -- 3.4 The Mechanisms of Electrode Reactions Occurring at the Cathode and Anode -- 3.5 Prospects for CO2 Conversion in Molten Salts -- 4 Conclusions -- References -- 7 Supercritical Carbon Dioxide Mediated Organic Transformations -- Abstract -- 1 Introduction -- 2 Applications of Supercritical Carbon Dioxide -- 2.1 Hydrogenation Reactions -- 2.2 Asymmetric Hydrogenation Reactions -- 2.3 Diels-Alder Reaction -- 2.4 Coupling Reaction -- 2.5 Oxidation Reaction -- 2.6 Baeyer-Villiger Oxidation Reaction -- 2.7 Iodination Reaction -- 2.8 Polymerization Reaction -- 2.9 Carbonylation Reaction -- 2.9.1 Acetalization Reaction -- 2.9.2 Olefin Metathesis Reaction -- 2.9.3 Synthesis of heterocycles -- Synthesis of α-alkylidene Cyclic Carbonates -- Synthesis of 4-Methyleneoxazolidin-2-Ones -- Synthesis of 5-Alkylidene-1, 3-Oxazolidin-2-Ones -- Synthesis of 6-Phenyl-3a, 4-Dihydro-1H-Cyclopenta[C]furan-5(3H)-One -- Synthesis of 3, 4, 5, 6-Tetraethyl-2H-Pyran-2-One -- 3 Conclusions -- Acknowledgements -- References -- 8 Theoretical Approaches to CO2 Transformations -- Abstract -- 1 Carbon Dioxide Properties -- 2 CO2 Transformation as an Undeniable Necessity -- 3 CO2 Activation -- 3.1 Methodologies of CO2 Activation -- 4 Theoretical Insight of CO2 Transformation -- 4.1 The Theoretical Approach in CO2 Conversion to Value-Added Chemicals -- 4.1.1 Carbon Monoxide -- 4.1.2 Methane -- 4.1.3 Methanol -- 4.1.4 Formic Acid -- 4.1.5 Heterocycles -- Cyclic Carbonates -- Cyclic Carbamate -- Quiznazoline-2,4(1H,3H)-Dione -- 4.1.6 Summary and Outlook -- 5 Theoretical Designing of Novel Catalysts Based on DFT Studies -- 5.1 Theoretical Designing: Problems and Opportunities -- 6 Conclusion -- References -- 9 Carbon Dioxide Conversion Methods -- Abstract -- 1 Introduction -- 2 Molecular Structure of CO2. , 3 Thermo-Kinetics of CO2 Conversion -- 4 CO2 Conversion Methods and Products -- 4.1 Fischer-Tropsch Gas-to-Liquid (GTL) -- 4.2 Mineralization -- 4.3 Chemical Looping Dry Reforming -- 4.4 Enzymatic Conversion -- 4.5 Photocatalytic and Photo-Electrochemical Conversion -- 4.6 Thermo-Chemical Conversion -- 4.7 Hydrogenation -- 4.8 Reforming -- 5 Economic Assessment of CO2Alteration to Valuable Products -- 5.1 Syngas -- 5.2 Methanol -- 5.3 Formic Acid -- 5.4 Urea -- 5.5 Dimethyl Carbonate (DMC) -- 6 Conclusions and Future Perspective -- Acknowledgements -- References -- 10 Closing the Carbon Cycle -- Abstract -- 1 Introduction -- 2 Methods to Capture CO2 -- 3 CO2 Capture Technologies -- 4 CO2 Capture from the Air -- 5 Biomass and Waste-Based Chemicals -- 6 Advantages of Biomass-Based Chemicals -- 7 Replacement of Carbon-Based Energy Resources -- 8 Biomass Energy -- 9 Wind Energy -- 10 Solar Energy -- 11 Ocean Energy -- 12 Geothermal Energy -- 13 Hydrothermal Energy -- 14 Conclusions -- References -- 11 Carbon Dioxide Utilization to Energy and Fuel: Hydrothermal CO2 Conversion -- Abstract -- 1 Introduction -- 2 Hydrothermal CO2 Conversion -- 2.1 Metals and Catalysts as Reductant -- 2.2 Organic Wastes as Reductant -- 2.3 Inorganic Wastes as Reductant -- 2.4 Biomass as Reductant -- 3 Conclusion -- References -- 12 Ethylenediamine-Carbonic Anhydrase Complex for CO2 Sequestration -- 1 Introduction -- 2 An Overview of Carbonic Anhydrase (CA) -- 3 Mechanism of Action for Biocarbonate Formation -- 4 Historical Background of Carbonic Anhydrase -- 5 Sources of Carbonic Anhydrase -- 6 Carbonic Anhydrase in Microorganism -- 6.1 Micrococcus Lylae, Micrococcus Luteus, and Pseudomonas Fragi -- 6.2 Bacillus Subtilis and Citrobacter Freundii -- 6.3 Neisseria Gonorrhoeae -- 6.4 Helicobacter Pylori -- 7 Plant Carbonic Anhydrase -- 8 Overview of CO2. , 9 Sources of Carbon Dioxide (CO2) -- 10 Effect of Carbon Dioxide (CO2) -- 11 Carbon Dioxide Capturing -- 12 Carbon Dioxide (CO2) Sequestration -- 13 Carbon Dioxide (CO2) Sequestration by Carbonic Anhydrase -- 14 Separation System for CO2 Sequestration -- 15 Cryogenic Separation -- 16 Membrane Separation -- 17 Absorption -- 18 Adsorption -- 19 Bioreactors for CO2 Sequestration -- 20 Carbonic Anhydrase Immobilization -- 21 Ethylenediamine for Carbon Dioxide (CO2) Capturing -- 22 CO2 Capturing and Sequestration with Ethylenediamine-Carbonic Anhydrase Complex -- 23 CO2 Capturing and Sequestration Design and Optimization: Challenges and Future Prospects -- 24 Conclusion -- References -- 13 Green Pathway of CO2 Capture -- Abstract -- 1 Introduction -- 2 Molecular Structure of Carbon Dioxide -- 3 CO2 Capture System -- 3.1 Post-Combustion System -- 3.2 Pre-Combustion System -- 3.3 Oxy-Fuel Combustion System -- 4 Absorption Technology -- 4.1 Green Absorption with Ionic Liquids -- 4.1.1 Properties and Uses of Ionic Liquids -- 4.1.2 CO2 Solubility in PILs -- 4.1.3 CO2 Absorption in PILs with Carboxylate Anion -- 4.2 Reaction Mechanism Involved in CO2-Absorption -- 5 Adsorption Technology -- 5.1 Organic Adsorbents -- 5.1.1 Activated Charcoal -- 5.1.2 Biochar -- 5.1.3 Metal-Organic Frameworks (MOFs) -- 5.2 Other CO2 Adsorbents -- 5.2.1 Metal Oxide-Based Absorbents -- 5.2.2 Zeolites -- 5.3 Biological Processes of CO2Sequestration -- 5.3.1 Carbon Utilization by Forest and Agricultural Management -- 5.3.2 Ocean Fertilization -- 5.3.3 CO2 Capture by Microalgae -- 5.4 Electrochemical Ways for CO2 Capture -- 6 Conclusion -- References -- 14 Carbon Derivatives from CO2 -- Abstract -- 1 Introduction -- 2 Artificial Photoreduction -- 3 Electrochemical Reduction -- 4 Hydrogenation -- 5 Synthesis of Organic Carbonates -- 6 Reforming. , 7 Photocatalytic Reduction of CO2 with Water.

Note: Cover -- Title Page -- Copyright -- Dedication -- Contents -- About the Editors -- Preface -- Chapter 1 Bioinspired Polydopamine and Composites for Biomedical Applications -- 1.1 Introduction -- 1.2 Synthesis of Polydopamine -- 1.2.1 Polymerization of Polydopamine -- 1.2.2 Synthesis of Polydopamine Nanostructures -- 1.3 Properties of Polydopamine -- 1.3.1 General Properties of Polydopamine -- 1.3.2 Electrical Properties of Polydopamine -- 1.4 Applications of Polydopamine -- 1.4.1 Biomedical Applications of Polydopamine -- 1.5 Conclusion and Future Prospectives -- References -- Chapter 2 Multifunctional Polymer-Dilute Magnetic Conductor and Bio-Devices -- 2.1 Introduction -- 2.2 Magnetic Semiconductor-Nanoparticle-Based Polymer Nanocomposites -- 2.3 Types of Magnetic Semiconductor Nanoparticles -- 2.3.1 Metal and Metal Oxide Nanoparticles -- 2.3.2 Ferrites -- 2.3.3 Dilute Magnetic Semiconductors -- 2.3.4 Manganites -- 2.4 Synthetic Strategies for Composite Materials -- 2.4.1 Physical Methods -- 2.4.2 Chemical Methods -- 2.5 Biocompatibility of Polymer/Semiconductor-Particle-Based Nanocomposites and Their Products for Biomedical Applications -- 2.5.1 Biocompatibility -- 2.6 Biomedical Applications -- References -- Chapter 3 Polymer-Inorganic Nanocomposite and Biosensors -- 3.1 Introduction -- 3.2 Nanocomposite Synthesis -- 3.3 Properties of Polymer-Based Nanocomposites -- 3.3.1 Mechanical Properties -- 3.3.2 Thermal Properties -- 3.4 Electrical Properties -- 3.5 Optical Properties -- 3.6 Magnetic Properties -- 3.7 Application of Polymer-Inorganic Nanocomposite in Biosensors -- 3.7.1 DNA Biosensors -- 3.7.2 Immunosensors -- 3.7.3 Aptamer Sensors -- 3.8 Conclusions -- References -- Chapter 4 Carbon Nanomaterial-Based Conducting Polymer Composites for Biosensing Applications -- 4.1 Introduction. , 4.2 Biosensor: Features, Principle, Types, and Its Need in Modern-Day Life -- 4.2.1 Important Features of a Successful Biosensor -- 4.2.2 Types of Biosensors -- 4.2.3 Need for Biosensors -- 4.3 Common Carbon Nanomaterials and Conducting Polymers -- 4.3.1 Carbon Nanotubes (CNTs) and Graphene (GN) -- 4.3.2 Conducting Polymers -- 4.4 Processability of CNTs and GN with Conducting Polymers, Chemical Interactions, and Mode of Detection for Biosensing -- 4.5 PANI Composites with CNT and GN for Biosensing Applications -- 4.5.1 Hydrogen Peroxide (H2O2) Sensors -- 4.5.2 Glucose Biosensors -- 4.5.3 Cholesterol Biosensors -- 4.5.4 Nucleic Acid Biosensors -- 4.6 PPy and PTh Composites with CNT and GN for Biosensing Applications -- 4.7 Conducting Polymer Composites with CNT and GN for the Detection of Organic Molecules -- 4.8 Conducting Polymer Composites with CNT and GN for Microbial Biosensing -- 4.9 Conclusion and Future Research -- References -- Chapter 5 Graphene and Graphene Oxide Polymer Composite for Biosensors Applications -- 5.1 Introduction -- 5.2 Polymer-Graphene Nanocomposites and Their Applications -- 5.2.1 Polyaniline -- 5.2.2 Polypyrrole -- 5.3 Conclusions,Challenges, and Future Scope -- References -- Chapter 6 Polyaniline Nanocomposite Materials for Biosensor Designing -- 6.1 Introduction -- 6.2 Importanceof PANI-Based Biosensors -- 6.3 Polyaniline-Based Glucose Biosensors -- 6.4 Polyaniline-Based Peroxide Biosensors -- 6.5 Polyaniline-Based Genetic Material Biosensors -- 6.6 Immunosensors -- 6.7 Biosensorsof Phenolic Compounds -- 6.8 Polyaniline-Based Biosensor for Water Quality Assessment -- 6.9 Scientific Concerns and Future Prospects of Polyaniline-Based Biosensors -- 6.10 Conclusion -- References -- Chapter 7 Recent Advances in Chitosan-Based Films for Novel Biosensor -- 7.1 Introduction -- 7.2 Chitosanas Novel Biosensor -- 7.3 Application. , 7.4 Conclusion and Future Perspectives -- Acknowledgment -- References -- Chapter 8 Self Healing Materials and Conductivity -- 8.1 Introduction -- 8.1.1 What Is Self-Healing? -- 8.1.2 History of Self-Healing Materials -- 8.1.3 What Can We Use Self-Healing Materials for? -- 8.1.4 Biomimetic Materials -- 8.2 Classification of Self-Healing Materials -- 8.2.1 Capsule-Based Self-Healing Materials -- 8.2.2 Vascular Self-Healing Materials -- 8.2.3 Intrinsic Self-Healing Materials -- 8.3 Conductivity in Self-Healing Materials -- 8.3.1 Applications and Advantages -- 8.3.2 Aspects of Conductive Self-Healing Materials -- 8.4 Current and Future Prospects -- 8.5 Conclusions -- References -- Chapter 9 Electrical Conductivity and Biological Efficacy of Ethyl Cellulose and Polyaniline-Based Composites -- 9.1 Introduction -- 9.2 Conductivity of EC Polymers -- 9.2.1 Synthesis of EC-Inorganic Composites -- 9.2.2 Conductivity of EC-Based Composites -- 9.3 Conductivity of PANI Polymer -- 9.3.1 Synthesis of PANI-Based Comp -- 9.3.2 Conductivity of PANI-Based Composites -- 9.4 Biological Efficacy of EC and PANI-Based Composites -- 9.5 Summary and Conclusion -- Acknowledgments -- References -- Chapter 10 Synthesis of Polyaniline-Based Nanocomposite Materials and Their Biomedical Applications -- 10.1 Introduction -- 10.2 Biomedical Applications of PANI-Supported Nanohybrid Materials -- 10.2.1 Biocompatibility -- 10.2.2 Antimicrobial Activity -- 10.2.3 Tissue Engineering -- 10.3 Conclusion -- Acknowledgment -- References -- Chapter 11 Electrically Conductive Polymers and Composites for Biomedical Applications -- 11.1 Introduction -- 11.2 Conducting Polymers -- 11.2.1 Conducting Polymer Synthesis -- 11.2.2 Types of Conducting Polymer Used for Biomedical Applications -- 11.3 Conductive Polymer Composite -- 11.3.1 Types of Conductive Polymer Composite. , 11.3.2 Methods for the Synthesis of Conductive Polymer Composites -- 11.4 Biomedical Applications of Conductive Polymers -- 11.4.1 Electrically Conductive Polymer Systems (ECPs) for Drug Targeting and Delivery -- 11.4.2 Electrically Conductive Polymer System (ECPs) for Tissue Engineering and Regenerative Medicine -- 11.4.3 Electrically Conductive Polymer Systems (ECPs) as Sensors of Biologically Important Molecules -- 11.5 Future Prospects -- 11.6 Conclusions -- References -- Index -- EULA.