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: 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: Intro -- front-matter -- Table of Contents -- Preface -- 1 -- Transition Metal Chalcogenides for Photoelectrochemical Water Splitting -- 1. Introduction -- 2. Typical structures of transition metal chalcogenides -- 3. Binary chalcogenides applied to photoelectrochemical water splitting -- 4. Transition metal-based ternary and multinary chalcogenides for photoelectrochemical water splitting -- 4.1 P-type copper-based chalcogenides -- 4.2. Silver-based chalcogenides for water splitting -- Conclusions -- References -- 2 -- Selection of Materials and Cell Design for Photoelectrochemical Decomposition of Water -- 1. Introduction -- 2. Principle and theory of water decomposition -- 3. Challenges in designing of a photoelectrochemical cell -- 4. Design configurations of PEC -- 4.1 Type 1 photo anodes -- 4.2 Type II heterojunction photomaterials -- 4.3 Type III wired type PEC tandem cells -- 4.4 Type IV wireless type PEC -- 4.5 Type V PV−EC systems -- Conclusions -- References -- 3 -- Interfacial Layer/Overlayer Effects in Photoelectrochemical Water Splitting -- 1. Introduction -- 2. PEC cell photoelectrode: Required characteristics and recent trends -- 3. Interface layering/over-layering: An effective strategy -- 4. Interface layering/over-layering of metal oxide semiconductors -- 4.1 Interface layering with BiVO4 -- 4.2 Interface layering with CuO/Cu2O -- 4.3 Interface layering with hematite (α-Fe2O3) -- 4.4 Interface layering with WO3 -- 4.5 Interface layering with TiO2 -- 5. Interface layering with carbon materials -- 6. Interface layering with low-cost non-metallic semiconductors -- 7. Interface layering/integration with metal nanoparticles -- Conclusion and future directions -- Acknowledgements -- References -- 4 -- Narrow Bandgap Semiconductors for Photoelectrochemical Water Splitting -- 1. Introduction. , 2. Narrow band gap materials as a strategy to improve photoresponse of the material -- 2.1 Bismuth sulfide (Bi2S3) -- 2.2 CuO -- 2.3 Fe2O3 -- 2.4 BiOI -- Spray Pyrolysis -- BiOI/BiOBr -- BiOI/TiO2 -- Conclusion -- References -- 5 -- Ti-based Materials for Photoelectrochemical Water Splitting -- 1. Introduction -- 2. Basic principle of PEC water splitting -- 3. Material selection for PEC water splitting -- 4. TiO2 photocatalyst for PEC water splitting -- 5. Tuning the photocatalytic of TiO2 into the visible light region -- Conclusion -- Acknowledgements -- References -- 6 -- BiVO4 Photoanodes for Photoelectrochemical Water Splitting -- 1. Introduction -- 2. Crystal and electronic band structure of BiVO4 -- 3. The band gap of monoclinic BiVO4 -- 3.1 BiVO4 photoanode band alignment at a liquid interface -- 4. Influence of crystal facet -- 5. Carrier dynamics in BiVO4 -- 6. Intrinsic defects/Oxygen vacancies in BiVO4 -- 7. Polarons in BiVO4 -- 8. Doping BiVO4 -- 8.1 W doping into BiVO4 -- 8.2 Mo doping into BiVO4 -- 8.3 Other dopants in BiVO4 -- 8.4 Lanthanide ion doping into BiVO4 -- 8.5 Codoping in BiVO4 (multiple ion doping) -- 9. The side of illumination on BiVO4 photoanode -- 10. Photo-charged BiVO4 -- 11. Hole blocking layer for BiVO4 -- 12. Catalyst coatings on BiVO4 photoanode -- 13. Plasmon-induced resonant energy transfer -- Conclusions and future perspective -- References -- 7 -- Noble Materials for Photoelectrochemical Water Splitting -- 1. Introduction -- 2. Fundamental properties of noble metals for photocatalytic activity -- 2.1 Fundamentals of the Localized Surface Plasmon Resonance (LSPR) -- 2.2 Schottky junction -- 3. Photoelectrodes materials -- 3.1 Titania (TiO2) -- 3.2 Haematite (Fe2O3) -- 3.3 Zinc oxide (ZnO) -- 4. Fundamental role of noble materials in PEC water splitting -- 4.1 Platinum (Pt) -- 4.2 Gold (Au) -- 4.3 Silver (Ag). , 4.4 Palladium (Pd) -- 4.5 Copper (Cu) -- 5. Noble bimetallic nanocomposites for PEC water splitting -- 5.1 Au-Pt bimetallic nanocomposites -- 5.2 Au-Pd bimetallic nanocomposites -- 5.3 Au-Ag bimetallic nanocomposites -- 5.4 Ag-Cu bimetallic nanocomposites -- 6. A brief note on bimetallic non-noble NPs for photoelectrochemical (PEC) water splitting -- Conclusion -- References -- back-matter -- Keyword Index -- About the Editors.

Note: Cover -- Title Page -- Copyright Page -- Contents -- Preface -- Chapter 1 Anti-Adhesive Coatings: A Technique for Prevention of Bacterial Surface Fouling -- 1.1 Bacterial Surface Fouling (Biofouling) -- 1.2 Negative Effects of Biofouling by Bacteria on Practical Applications -- 1.3 Anti-Adhesive Coatings for Preventing Bacterial Surface Fouling -- 1.3.1 Hydrophilic Polymers -- 1.3.2 Zwitterionic Polymers -- 1.3.3 Super-Hydrophobic Polymers -- 1.3.4 Slippery Liquid Infused Porous Surfaces (SLIPS) -- 1.3.5 Protein and Glycoprotein-Based Coatings -- 1.4 Bifunctional Coatings With Anti-Adhesive and Antibacterial Properties -- 1.5 Concluding Remarks -- Acknowledgments -- References -- Chapter 2 Lignin-Based Adhesives -- 2.1 Introduction -- 2.2 Native Lignin and Source of Technical Lignin -- 2.2.1 Native Lignin -- 2.2.2 Technical Lignins -- 2.3 Limitations of Technical Lignins -- 2.3.1 Heterogeneity of Technical Lignins -- 2.3.2 Reactivity of Technical Lignins -- 2.4 Lignin Pre-Treatment/Modification for Adhesive Application -- 2.4.1 Physical Pre-Treatment -- 2.4.2 Chemical Modification -- 2.5 Challenges and Prospects -- 2.6 Conclusions -- References -- Chapter 3 Green Adhesive for Industrial Applications -- 3.1 Introduction -- 3.2 Advanced Green Adhesives Categories- Industrial Applications -- 3.2.1 Keta Spire Poly Etherether Ketone Powder Coating -- 3.2.2 Bio-Inspired Adhesive in Robotics Field Application -- 3.2.3 Bio-Inspired Synthetic Adhesive in Space Application -- 3.2.3.1 Micro Structured Dry Adhesive Fabrication for Space Application -- 3.2.4 Natural Polymer Adhesive for Wood Panel Industry -- 3.2.5 Tannin Based Bio-Adhesive for Leather Tanning Industry -- 3.2.6 Conductive Adhesives in Microelectronics Industry -- 3.2.7 Bio-Resin Adhesive in Dental Industry -- 3.2.8 Green Adhesive in Fiberboard Industry -- 3.3 Conclusions and Future Scope. , References -- Chapter 4 Green Adhesives for Biomedical Applications -- 4.1 Introduction -- 4.2 Main Raw Materials of Green Adhesives: Structure, Composition, and Properties -- 4.2.1 Chitosan -- 4.2.2 Alginate -- 4.2.3 Lignin -- 4.2.4 Lactic Acid PLA -- 4.3 Properties Characterization of Green Adhesives for Biomedical Applications -- 4.3.1 Diffraction X-Rays (DRX) -- 4.3.2 Atomic Force Microscopy (AFM) -- 4.3.3 Scanning Electron Microscope (SEM Images) -- 4.3.4 Wettability or Contact Angle (CA) -- 4.3.5 Fourier Transform Infrared Spectroscopy (FTIR) -- 4.3.6 Inductively Coupled Plasma-Optical Emission Spectrometry (ICP-OES) -- 4.3.7 Thermal Analysis (TG/DTG/DTA and DSC Curves) -- 4.3.8 Surface Area and Porosimetry Analyzer (ASAP) -- 4.3.9 Mechanical Properties of Green Adhesives -- 4.4 Biomedical Applications of Natural Polymers -- 4.4.1 Alginate -- 4.4.1.1 Biomedical Applications of Alginate -- 4.4.2 Chitosan -- 4.4.2.1 Biomedical Applications of Chitosan -- 4.4.3 Lignin -- 4.4.3.1 Biomedical Applications of Lignin -- 4.4.4 Polylactide (PLA) -- 4.4.4.1 Biomedical Applications of PLA -- 4.5 Final Considerations -- Acknowledgements -- References -- Chapter 5 Waterborne Adhesives -- 5.1 Introduction -- 5.1.1 Motivation for the Use of Waterborne Adhesives -- 5.1.1.1 Sustainability and Environment Regulations -- 5.1.1.2 Circular Economy -- 5.1.1.3 Avoid Harmful Emissions -- 5.1.1.4 Development of Novel and Sustainable End Products -- 5.1.2 Environmental Effects and Mankind Toxicity Analysis -- 5.2 Performance of Waterborne Adhesives: An Overview -- 5.2.1 Waterborne Polyurethane (WBPU) Adhesives -- 5.2.1.1 Chemical Structure of Waterborne PU -- 5.2.1.2 Performances of WBPU Adhesives -- 5.2.2 Waterborne Epoxy Adhesive -- 5.3 Conclusions -- References -- Chapter 6 Using Polyfurfuryl Alcohol as Thermoset Adhesive/Sealant -- 6.1 Introduction. , 6.2 Furfuryl Alcohol as Adhesives -- 6.3 Polyfurfuryl Alcohol as Sealants -- 6.3.1 Effect of Different Parameters on the Curing of PFA-Based Sealants -- 6.4 Applications -- 6.5 Conclusions -- Acknowledgement -- References -- Chapter 7 Bioadhesives -- 7.1 Introduction -- 7.2 History of Bioadhesives -- 7.3 Classification of Bioadhesives -- 7.4 Mechanism of Bioadhesion -- 7.4.1 Mechanical Interlocking -- 7.4.2 Chain Entanglement -- 7.4.3 Intermolecular Bonding -- 7.4.4 Electrostatic Bonding -- 7.5 Testing of Bioadhesives -- 7.5.1 In Vitro Methods -- 7.5.1.1 Shear Stress Measurements -- 7.5.1.2 Peel Strength Evaluation -- 7.5.1.3 Flow Through Experiment and Plate Method -- 7.5.2 Ex Vitro Methods -- 7.5.2.1 Adhesion Weight Method -- 7.5.2.2 Fluorescent Probe Methods -- 7.5.2.3 Falling Liquid Film Method -- 7.6 Application of Bioadhesives -- 7.6.1 Bioadhesives as Drug Delivery Systems -- 7.6.2 Bioadhesives as Fibrin Sealants -- 7.6.3 Bioadhesives as Protein-Based Adhesives -- 7.6.4 Bioadhesives in Tissue Engineering -- 7.7 Conclusion -- References -- Chapter 8 Polysaccharide-Based Adhesives -- 8.1 Introduction -- 8.2 Cellulose-Derived Adhesive -- 8.2.1 Esterification -- 8.2.1.1 Cellulose Nitrate -- 8.2.1.2 Cellulose Acetate -- 8.2.1.3 Cellulose Acetate Butyrate -- 8.2.2 Etherification -- 8.2.2.1 Methyl Cellulose -- 8.2.2.2 Ethyl Cellulose -- 8.2.2.3 Carboxymethyl Cellulose -- 8.3 Starch-Derived Adhesives -- 8.3.1 Alkali Treatment -- 8.3.2 Acid Treatment -- 8.3.3 Heating -- 8.3.4 Oxidation -- 8.4 Natural Gums Derived-Adhesives -- 8.5 Fermentation-Based Adhesives -- 8.6 Enzyme Cross-Linked-Based Adhesives -- 8.7 Micro-Biopolysaccharide-Based Adhesives -- 8.8 Mechanism of Adhesion -- 8.9 Tests for Adhesion Strength -- 8.10 Applications -- 8.10.1 Biomedical Applications -- 8.10.2 Food Stuffs Applications -- 8.10.3 Pharmaceutical Applications. , 8.10.4 Agricultural Applications -- 8.10.5 Cigarette Manufacturing -- 8.10.6 Skin Cleansing Applications -- 8.11 Conclusion -- References -- Chapter 9 Wound Healing Adhesives -- 9.1 Introduction -- 9.2 Wound -- 9.2.1 Types of Wounds -- 9.2.1.1 Acute Wounds -- 9.2.1.2 Chronic Wounds -- 9.3 Structure and Function of the Skin -- 9.4 Mechanism of Wound Healing -- 9.5 Wound Closing Techniques -- 9.6 Wound Healing Adhesives -- 9.7 Types of Wound Healing Adhesives Based Upon Site of Application -- 9.7.1 External Use Wound Adhesives -- 9.7.1.1 Steps for Applying External Wound Healing Adhesives on Skin [30] -- 9.7.2 Internal Use Wound Adhesives -- 9.8 Types of Wound Healing Adhesives Based Upon Chemistry -- 9.8.1 Natural Wound Healing Adhesives -- 9.8.1.1 Fibrin Sealants/Fibrin-Based Tissue Adhesives -- 9.8.1.2 Albumin-Based Adhesives -- 9.8.1.3 Collagen and Gelatin-Based Wound Healing Adhesives -- 9.8.1.4 Starch -- 9.8.1.5 Chitosan -- 9.8.1.6 Dextran -- 9.8.2 Synthetic Wound Healing Adhesives -- 9.8.2.1 Cyanoacrylate -- 9.8.2.2 Poly Ethylene Glycol-Based Wound Adhesives (PEG) -- 9.8.2.3 Hydrogels -- 9.8.2.4 Polyurethane -- 9.9 Summary -- References -- Chapter 10 Green-Wood Flooring Adhesives -- 10.1 Introduction -- 10.2 Wood Flooring -- 10.2.1 Softwood Flooring -- 10.2.2 Hardwood Flooring -- 10.2.3 Engineered Wood Flooring -- 10.2.4 Laminate Flooring -- 10.2.5 Vinyl Flooring -- 10.2.6 Agricultural Residue Wood Flooring Panels -- 10.3 Recent Advances About Green Wood-Flooring Adhesives -- 10.3.1 Xylan -- 10.3.2 Modified Cassava Starch Bioadhesives -- 10.3.3 High-Efficiency Bioadhesive -- 10.3.4 Bioadhesive Made From Soy Protein and Polysaccharide -- 10.3.5 Green Cross-Linked Soy Protein Wood Flooring Adhesive -- 10.3.6 "Green" Bio-Thermoset Resins Derived From Soy Protein Isolate and Condensed Tannins. , 10.3.7 Development of Green Adhesives Using Tannins and Lignin for Fiberboard Manufacturing -- 10.3.8 Cottonseed Protein as Wood Adhesives -- 10.3.9 Chitosan as an Adhesive -- 10.3.10 PE-cg-MAH Green Wood Flooring Adhesive -- References -- Chapter 11 Synthetic Binders for Polymer Division -- List of Abbreviations -- 11.1 Introduction -- 11.2 Classification of Adhesives Based on Its Chemical Properties -- 11.2.1 Thermoset Adhesives -- 11.2.2 Thermoplastic Adhesives -- 11.2.3 Adhesive Blends -- 11.3 Adhesives Characteristics -- 11.4 Adhesives Classification Based on Its Function -- 11.4.1 Permanent Adhesives -- 11.4.2 Removable Adhesives -- 11.4.3 Repositionable Adhesives -- 11.4.4 Blended Adhesives -- 11.4.5 Anaerobic Adhesives -- 11.4.6 Aromatic Polymer Adhesives -- 11.4.7 Asphalt -- 11.4.8 Adhesives Based on Butyl Rubber -- 11.4.9 Cellulose Ester Adhesives -- 11.4.10 Adhesives Based on Cellulose Ether -- 11.4.11 Conductive Adhesives -- 11.4.12 Electrically Conductive Adhesive Materials -- 11.4.13 Thermally Conductive Adhesives -- 11.5 Resin -- 11.5.1 Unsaturated Polyester Resin -- 11.5.2 Monomers -- 11.5.2.1 Unsaturated Polyester -- 11.5.2.2 Alcohol Constituents -- 11.5.2.3 Constituents Like Anhydride and Acid -- 11.5.3 Vinyl Monomers of Unsaturated Polyester Resins -- 11.5.4 Styrenes -- 11.5.5 Acrylates and Methacrylates -- 11.5.6 Vinyl Ethers -- 11.5.7 Fillers -- 11.6 Polyurethanes -- 11.6.1 Monomers -- 11.6.1.1 Diisocyanates -- 11.6.1.2 Phosgene Route -- 11.6.1.3 Phosgene-Free Route -- 11.6.1.4 Polyols -- 11.6.1.5 Vinyl Functionalized Polyols -- 11.6.1.6 Polyols Based on Modified Polyurea -- 11.6.1.7 Polyols Based on Polyester -- 11.6.1.8 Acid and Alcohols-Based Polyesters -- 11.6.2 Rectorite Nanocomposites -- 11.6.3 Zeolite -- 11.7 Epoxy Resins -- 11.7.1 Monomers -- 11.7.1.1 Epoxides -- 11.7.1.2 Hyper Branched Polymers. , 11.7.2 Epoxide Resins Based on Liquid Crystalline Structure.

Note: Cover -- Title Page -- Copyright Page -- Contents -- Preface -- Chapter 1 Application of MOFs and Their Derived Materials in Sensors -- 1.1 Introduction -- 1.2 Application of MOFs and Their Derived Materials in Sensors -- 1.2.1 Optical Sensor -- 1.2.1.1 Colorimetric Sensor -- 1.2.1.2 Fluorescence Sensor -- 1.2.1.3 Chemiluminescent Sensor -- 1.2.2 Electrochemical Sensor -- 1.2.2.1 Amperometric Sensor -- 1.2.2.2 Impedimetric, Electrochemiluminescence, and Photoelectrochemical Sensor -- 1.2.3 Field-Effect Transistor Sensor -- 1.2.4 Mass-Sensitive Sensor -- 1.3 Conclusion -- Acknowledgments -- References -- Chapter 2 Applications of Metal-Organic Frameworks (MOFs) and Their Derivatives in Piezo/Ferroelectrics -- 2.1 Introduction -- 2.1.1 Brief Introduction to Piezo/Ferroelectricity -- 2.2 Fundamentals of Piezo/Ferroelectricity -- 2.3 Metal-Organic Frameworks for Piezo/ Ferroelectricity -- 2.4 Ferro/Piezoelectric Behavior of Various MOFs -- 2.5 Conclusion -- References -- Chapter 3 Fabrication and Functionalization Strategies of MOFs and Their Derived Materials "MOF Architecture" -- 3.1 Introduction -- 3.2 Fabrication and Functionalization of MOFs -- 3.2.1 Metal Nodes -- 3.2.2 Organic Linkers -- 3.2.3 Secondary Building Units -- 3.2.4 Synthesis Methods -- 3.2.4.1 Hydrothermal and Solvothermal Method -- 3.2.4.2 Microwave Synthesis -- 3.2.4.3 Electrochemical Method -- 3.2.4.4 Mechanochemical Synthesis -- 3.2.4.5 Sonochemical (Ultrasonic Assisted) Method -- 3.2.4.6 Diffusion Method -- 3.2.4.7 Template Method -- 3.2.5 Synthesis Strategies -- 3.3 MOF Derived Materials -- 3.4 Conclusion -- References -- Chapter 4 Application of MOFs and Their Derived Materials in Molecular Transport -- 4.1 Introduction -- 4.2 MOFs as Nanocarriers for Membrane Transport -- 4.2.1 MIL-89 -- 4.2.2 MIL-88A -- 4.2.3 MIL-100 -- 4.2.4 MIL-101 -- 4.2.5 MIL-53 -- 4.2.6 ZIF-8. , 4.2.7 Zn-TATAT -- 4.2.8 BioMOF-1 (Zn) -- 4.2.9 UiO (Zr) -- 4.3 Conclusion -- References -- Chapter 5 Role of MOFs as Electro/-Organic Catalysts -- 5.1 What Is MOFs -- 5.2 MOFs as Electrocatalyst in Sensing Applications -- 5.3 MOFs as Organic Catalysts in Organic Transformations -- 5.4 Conclusion and Future Prospects -- References -- Chapter 6 Application of MOFs and Their Derived Materials in Batteries -- 6.1 Introduction -- 6.2 Metal-Organic Frameworks -- 6.2.1 Classification and Properties of Metal-Organic Frameworks -- 6.2.2 Potential Applications of MOFs -- 6.2.3 Synthesis of MOFs -- 6.3 Polymer Electrolytes -- 6.3.1 Historical Perspectives and Classification of Polymer Electrolytes -- 6.3.2 MOF Based Polymer Electrolytes -- 6.4 Ionic Liquids -- 6.4.1 Properties of Ionic Liquids -- 6.4.2 Ionic Liquid Incorporated MOF -- 6.5 Ion Transport in Polymer Electrolytes -- 6.5.1 General Description of Ionic Conductivity -- 6.5.2 Models for Ionic Transport in Polymer Electrolytes -- 6.5.3 Impedance Spectroscopy and Ionic Conductivity Measurements -- 6.5.4 Concept of Mismatch and Relaxation -- 6.5.5 Scaling of ac Conductivity -- 6.6 IL Incorporated MOF Based Composite Polymer Electrolytes -- 6.7 Conclusion and Perspectives -- References -- Chapter 7 Fine Chemical Synthesis Using Metal-Organic Frameworks as Catalysts -- 7.1 Introduction -- 7.2 Oxidation Reaction -- 7.2.1 Epoxidation -- 7.2.2 Sulfoxidation -- 7.2.3 Aerobic Oxidation of Alcohols -- 7.3 1,3-Dipolar Cycloaddition Reaction -- 7.4 Transesterification Reaction -- 7.5 C-C Bond Formation Reactions -- 7.5.1 Heck Reactions -- 7.5.2 Sonogashira Coupling -- 7.5.3 Suzuki Coupling -- 7.6 Conclusion -- References -- Chapter 8 Application of Metal Organic Framework and Derived Material in Hydrogenation Catalysis -- 8.1 Introduction -- 8.1.1 The Active Centers in Parent MOF Materials. , 8.1.2 The Active Centers in MOF Catalyst -- 8.1.3 Metal Nodes -- 8.2 Hydrogenation Reactions -- 8.2.1 Hydrogenation of Alpha-Beta Unsaturated Aldehyde -- 8.2.2 Hydrogenation of Cinnamaldehyde -- 8.2.3 Hydrogenation of Nitroarene -- 8.2.4 Hydrogenation of Nitro Compounds -- 8.2.5 Hydrogenation of Benzene -- 8.2.6 Hydrogenation of Quinoline -- 8.2.7 Hydrogenation of Carbon Dioxide -- 8.2.8 Hydrogenation of Aromatics -- 8.2.9 Hydrogenation of Levulinic Acid -- 8.2.10 Hydrogenation of Alkenes and Alkynes -- 8.2.11 Hydrogenation of Phenol -- 8.3 Conclusion -- References -- Chapter 9 Application of MOFs and Their Derived Materials in Solid-Phase Extraction -- 9.1 Solid-Phase Extraction -- 9.1.1 Materials in SPE -- 9.2 MOFs and COFs in Miniaturized Solid-Phase Extraction (µSPE) -- 9.3 MOFs and COFs in Miniaturized Dispersive Solid-Phase Extraction (D-µSPE) -- 9.4 MOFs and COFs in Magnetic-Assisted Miniaturized Dispersive Solid-Phase Extraction (m-D-µSPE) -- 9.5 Concluding Remarks -- Acknowledgments -- References -- Chapter 10 Anticancer and Antimicrobial MOFs and Their Derived Materials -- 10.1 Introduction -- 10.2 Anticancer MOFs -- 10.2.1 MOFs as Drug Carriers -- 10.2.2 MOFs in Phototherapy -- 10.3 Antibacterial MOFs -- 10.4 Antifungal MOFs -- References -- Chapter 11 Theoretical Investigation of Metal-Organic Frameworks and Their Derived Materials for the Adsorption of Pharmaceutical and Pe -- 11.1 Introduction -- 11.2 General Synthesis Routes -- 11.2.1 Hydrothermal Synthesis -- 11.2.2 Solvothermal Synthesis of MOFs -- 11.2.3 Room Temperature Synthesis -- 11.2.4 Microwave Assisted Synthesis -- 11.2.5 Mechanochemical Synthesis -- 11.2.6 Electrochemical Synthesis -- 11.3 Postsynthetic Modification in MOF -- 11.4 Computational Method -- 11.5 Results and Discussion. , 11.5.1 Binding Behavior Between MIL-100 With the Adsorbates (Diclofenac, Ibuprofen, Naproxen, and Oxybenzone) -- 11.6 Conclusion -- References -- Chapter 12 Metal-Organic Frameworks and Their Hybrid Composites for Adsorption of Volatile Organic Compounds -- 12.1 Introduction -- 12.2 VOCs and Their Potential Hazards -- 12.2.1 Other Sources of VOCs -- 12.3 VOCs Removal Techniques -- 12.4 Fabricated MOF for VOC Removal -- 12.4.1 MIL Series MOFs -- 12.4.2 Isoreticular MOFs -- 12.4.2.1 Adsorption Comparison of the Isoreticular MOFs -- 12.4.3 NENU Series MOFs -- 12.4.4 MOF-5, Eu-MOF, and MOF-199 -- 12.4.5 Amine-Impregnated MIL-100 -- 12.4.6 Biodegradable MOFs MIL-88 Series -- 12.4.7 Catalytic MOFs -- 12.4.8 Photo-Degradating MOFs -- 12.4.9 Some Other Studied MOFs -- 12.5 MOF Composites -- 12.5.1 MIL-101 Composite With Graphene Oxide -- 12.5.2 MIL-101 Composite With Graphite Oxide -- 12.6 Generalization Adsorptive Removal of VOCs by MOFs -- 12.7 Simple Modeling the Adsorption -- 12.7.1 Thermodynamic Parameters -- 12.7.2 Dynamic Sorption Methods -- 12.8 Factor Affecting VOCs Adsorption -- 12.8.1 Breathing Phenomena -- 12.8.2 Activation of MOFs -- 12.8.3 Applied Pressure -- 12.8.4 Relative Humidity -- 12.8.5 Breakthrough Conditions -- 12.8.6 Functional Group of MOFs -- 12.8.7 Concentration, Molecular Size, and Type of VOCs -- 12.9 Future Perspective -- References -- Chapter 13 Application of Metal-Organic Framework and Their Derived Materials in Electrocatalysis -- List of Abbreviations -- 13.1 Introduction -- 13.2 Perspective Synthesis of MOF and Their Derived Materials -- 13.3 MOF for Hydrogen Evolution Reaction -- 13.4 MOF for Oxygen Evolution Reaction -- 13.5 MOF for Oxygen Reduction Reaction -- 13.6 MOF for CO2 Electrochemical Reduction Reaction -- 13.6.1 Electrosynthesis of MOF for CO2 Reduction -- 13.6.2 Composite Electrodes as MOF for CO2 Reduction. , 13.6.3 Continuous Flow Reduction of CO2 -- 13.6.4 CO2 Electrochemical Reduction in Ionic Liquid -- 13.7 MOF for Electrocatalytic Sensing -- 13.8 Electrocatalytic Features of MOF -- 13.9 Conclusion -- Acknowledgment -- References -- Chapter 14 Applications of MOFs and Their Composite Materials in LightDriven Redox Reactions -- 14.1 Introduction -- 14.1.1 MOFs as Photocatalysts -- 14.1.2 Charge Transfer Mechanisms -- 14.1.3 Methods of Synthesis -- 14.2 Pristine MOFs and Their Application in Photocatalysis -- 14.2.1 Group 4 Metallic Clusters -- 14.2.2 Groups 8, 9, and 10 Metallic Clusters -- 14.2.3 Group 11 Metallic Clusters -- 14.2.4 Group 12 Metallic Clusters -- 14.3 Metal Nanoparticles-MOF Composites and Their Application in Photocatalysis -- 14.3.1 Ag-MOF Composites -- 14.3.2 Au-MOF Composites -- 14.3.3 Cu-MOF Composites -- 14.3.4 Pd-MOF Composites -- 14.3.5 Pt-MOF Composites -- 14.4 Semiconductor-MOF Composites and Their Application in Photocatalysis -- 14.4.1 TiO2-MOF Composites -- 14.4.2 Graphitic Carbon Nitride-MOF Composites -- 14.4.3 Bismuth-Based Semiconductors -- 14.4.4 Reduced Graphene Oxide-MOF Composites -- 14.4.5 Silver-Based Semiconductors -- 14.4.6 Other Semiconductors -- 14.5 MOF-Based Multicomponent Composites and Their Application in Photocatalysis -- 14.5.1 Semiconductor-Semiconductor-MOF Composites -- 14.5.2 Semiconductor-Metal-MOF Composites -- 14.6 Conclusions -- References -- Index -- Also of Interest -- Check out these other forthcoming and published titles from Scrivener Publishing -- EULA.

Note: Cover -- Half Title -- Title Page -- Copyright Page -- Table of Contents -- Preface -- Editors -- Contributors -- Chapter 1: Introduction to Porous Polymers -- 1.1 Introduction -- 1.2 Types of Porous Polymers -- 1.3 Synthetic Methods for Porous Polymer Network -- 1.4 Conclusion -- References -- Chapter 2: Hyper-crosslinked Polymers -- 2.1 Introduction -- 2.1.1 Overview -- 2.1.2 Porous Polymer -- 2.1.3 Crosslinking -- 2.2 Hyper-crosslinked Polymers -- 2.3 Synthesis Methods of HCPs -- 2.3.1 Post-crosslinking Polymer Precursors -- 2.3.2 Direct One-Step Polycondensation -- 2.3.3 Knitting Rigid Aromatic Building Blocks by External Crosslinkers -- 2.4 Structure and Morphology of HCPs -- 2.4.1 Nanoparticles -- 2.4.2 Hollow Capsules -- 2.4.3 2D Membranes -- 2.4.4 Monoliths -- 2.5 HCPs Properties -- 2.5.1 Polymer Surface -- 2.5.1.1 Hydrophilicity -- 2.5.1.2 Hydrophobicity -- 2.5.1.3 Amphiphilicity -- 2.5.2 Porosity and Surface Area -- 2.5.3 Swelling Behavior -- 2.5.4 Thermomechanical Properties -- 2.6 Functionalization of HCPs -- 2.7 Characterization of HCPs -- 2.7.1 Compositional and Structural Characterization -- 2.7.2 Morphological Characterization -- 2.7.3 Porosity and Surface Area Analysis -- 2.7.4 Other Analysis -- 2.8 Applications -- 2.8.1 Storage Capacity -- 2.8.1.1 Storage of Hydrogen -- 2.8.1.2 Storage of Methane -- 2.8.1.3 CO 2 Capture -- 2.8.2 Environmental Remediation -- 2.8.3 Heterogeneous Catalysis -- 2.8.4 Drug Delivery -- 2.8.5 Sensing -- 2.8.6 Other Applications -- 2.9 Conclusion -- References -- Chapter 3: Porous Ionic Polymers -- 3.1 Introduction: A Distinctive Feature of the Porous Structure of Ionic Polymers -- 3.2 Ionic Polymers in Dry State -- 3.3 Ionic Polymers in Swollen State: Hsu-Gierke Model -- 3.4 Modifications of Hsu-Gierke Model: Hydration of Ion Exchange Polymers. , 3.5 Methods for Research of Porous Structure of Ionic Polymers -- 3.5.1 Nitrogen Adsorption-Desorption -- 3.5.2 Mercury Intrusion -- 3.5.3 Adsorption-Desorption of Water Vapor -- 3.5.4 Differential Scanning Calorimetry -- 3.5.5 Standard Contact Porosimetry -- 3.6 Conclusions -- References -- Chapter 4: Analysis of Qualitative and Quantitative Criteria of Porous Plastics -- 4.1 Introduction -- 4.2 Sorting of Porous Polymers -- 4.2.1 Macroporous Polymers -- 4.2.2 Microporous Polymers -- 4.2.3 Mesoporous Polymers -- 4.3 Methodology -- 4.3.1 AHP Analysis -- 4.4 Conclusions -- References -- Chapter 5: Novel Research on Porous Polymers Using High Pressure Technology -- 5.1 Background -- 5.2 Porous Polymers Based on Natural Polysaccharides -- 5.3 Parameters Involved in the Porous Polymers Processing by High Pressure -- 5.4 Supercritical Fluid Drying for Porous Polymers Processing -- 5.5 Porous Polymers for Foaming and Scaffolds by Supercritical Technology -- 5.6 Supercritical CO 2 Impregnation in Porous Polymers for Food Packaging -- 5.7 Synthesis of Porous Polymers by Supercritical Emulsion Templating -- 5.8 Porous Polymers as Supports for Catalysts Materials by Supercritical Fluid -- 5.9 Porous Metal-Organic Frameworks Polymers by Supercritical Fluid Processing -- 5.10 Concluding Remarks -- Acknowledgments -- References -- Chapter 6: Porous Polymer for Heterogeneous Catalysis -- 6.1 Introduction -- 6.2 Stability and Functionalization of POPs -- 6.3 Strategies for Synthesizing POP Catalyst -- 6.3.1 Co-polymerization -- 6.3.1.1 Acidic and Basic Groups -- 6.3.1.2 Ionic Groups -- 6.3.1.3 Ligand Groups -- 6.3.1.4 Chiral Groups -- 6.3.1.5 Porphyrin Group -- 6.3.2 Self-polymerization -- 6.3.2.1 Organic Ligand Groups -- 6.3.2.2 Organocatalyst Groups -- 6.3.2.3 Ionic Groups -- 6.3.2.4 Chiral Ligand Groups -- 6.3.2.5 Porphyrin Groups. , 6.4 Applications of Various Porous Polymers -- 6.4.1 CO 2 Capture and Utilization -- 6.4.1.1 Ionic Liquid/Zn-PPh 3 Integrated POP -- 6.4.1.1.1 Mechanism of the Cycloaddition Reaction -- 6.4.1.2 Triphenylphosphine-based POP -- 6.4.2 Energy Storage -- 6.4.3 Heterogeneous Catalysis -- 6.4.3.1 Cu(II) Complex on Pyridine-based POP for Nitroarene Reduction -- 6.4.3.2 POP-supported Rhodium for Hydroformylation of Olefins -- 6.4.3.3 Ni(II)-metallated POP for Suzuki-Miyaura Crosscoupling Reaction -- 6.4.3.4 Ru-loaded POP for Decomposition of Formic Acid to H 2 -- 6.4.3.5 Porphyrin-based POP to Support Mn Heterogeneous Catalysts for Selective Oxidation of Alcohols -- 6.4.3.5.1 Mechanism of the Oxidation of Alcohols by TFP-DPMs -- 6.4.4 Photocatalysis -- 6.4.4.1 Conjugated Porous Polymer Based on Phenanthrene Units -- 6.4.4.2 (dipyrrin)(bipyridine)ruthenium(II) Visible Light Photocatalyst -- 6.4.4.3 Carbazole-based CMPs for C-3 Functionalization of Indoles -- 6.4.4.3.1 Mechanism of C-3 Formylation of N-methylindole by CMP-CSU6 Polymer Catalyst -- 6.4.4.3.2 The Mechanism for C-3 Thiocyanation of 1H-indole -- 6.4.5 Electrocatalysis -- 6.4.5.1 Redox-active N-containing CPP for Oxygen Reduction Reaction (ORR) -- References -- Chapter 7: Triazine Porous Frameworks -- 7.1 Introduction -- 7.2 Synthetic Procedures of CTFs and Their Structural Designs -- 7.2.1 Ionothermal Trimerization Strategy -- 7.2.2 High Temperature Phosphorus Pentoxide (P 2 O 5)-Catalyzed Method -- 7.2.3 Amidine-based Polycondensation Methods -- 7.2.4 Superacid Catalyzed Method -- 7.2.5 Friedel-Crafts Reaction Method -- 7.3 Applications of CTFs -- 7.3.1 Adsorption and Separation -- 7.3.1.1 CO 2 Capture and Separation -- 7.3.1.2 The Removal of Pollutants -- 7.3.2 Heterogeneous Catalysis -- 7.3.3 Applications for Energy Storage and Conversion -- 7.3.3.1 Metal-Ion Batteries -- 7.3.3.2 Supercapacitors. , 7.3.4 Electrocatalysis -- 7.3.5 Photocatalysis -- 7.3.6 Other Applications of CTFs -- References -- Chapter 8: Advanced Separation Applications of Porous Polymers -- 8.1 Introduction -- 8.2 Advanced Separation Applications -- 8.3 Separation through Adsorption -- 8.4 Water Treatment -- 8.5 Conclusion -- Abbreviations -- References -- Chapter 9: Porous Polymers for Membrane Applications -- 9.1 Introduction -- 9.2 Introduction to Synthesis of Porous Polymeric Particles -- 9.3 Preparation of Porous Polymeric Membrane -- 9.4 Morphology of Membrane and Its Parameters -- 9.5 Emerging Applications of Porous Polymer Membranes -- 9.6 Polysulfone and Polyvinylidene Fluoride Used as Porous Polymers for Membrane Application -- 9.6.1 Polysulfone Membranes -- 9.6.2 Polyvinylidene Fluoride Membranes -- 9.7 Use of Porous Polymeric Membranes for Sensing Application -- 9.8 Use of Porous Polymeric Electrolytic Membranes Application -- 9.9 Use of Porous Polymeric Membrane for Numerical Modeling and Optimization -- 9.10 Use of Porous Polymers for Biomedical Application -- 9.11 Use of Porous Polymeric Membrane in Tissue Engineering -- 9.12 Use of Porous Polymeric Membrane in Wastewater Treatment -- 9.13 Use of Porous Polymeric Membrane for Dye Rejection Application -- 9.14 Porous Polymeric Membrane Antifouling Application -- 9.15 Porous Polymeric Membrane Used for Fuel Cell Application -- 9.16 Conclusion -- References -- Chapter 10: Porous Polymers in Solar Cells -- 10.1 Introduction -- 10.1.1 Si-based Solar Cells -- 10.1.2 Thin-film Solar Cells -- 10.1.3 Organic Solar Cells -- 10.2 Porous Polymers in DSSCs -- 10.2.1 Porous Polymers in Electrodes -- 10.2.2 Porous Polymer as a Counter Electrode -- 10.2.3 Porous Polymers in TiO 2 Photoanode -- 10.2.4 Porous Polymers in Electrolyte -- 10.2.5 Porous Polymer as Energy Conversion Film. , 10.2.5.1 Polyvinylidene Fluoride-co-Hexafluoropropylene (PVDF-HFP) Membranes -- 10.2.5.2 Pyridine-based CMPs Aerogels (PCMPAs) -- 10.2.6 Porous Polymers in Coating of Solar Cell -- 10.2.7 Porous Polymers as Photocatalyst or Electrocatalyst -- 10.3 Perovskite Solar Cells -- 10.3.1 Porous Polymers in Electron Transport Layers -- 10.3.2 Porous Polymers in Hole Transport Layers -- 10.3.3 Porous Polymer as Energy Conversion Film -- 10.3.4 Porous Polymers as Interlayers -- 10.3.5 Porous Polymers in Morphology Regulations -- 10.4 Porous Polymers in Silicon Solar Cell -- 10.5 Miscellaneous -- 10.5.1 Porous Polymers in Solar Evaporators -- 10.5.2 Charge Separation Systems in Solar Cells -- 10.5.3 Porous Polymers in ZnO Photoanode -- 10.6 Conclusions -- References -- Chapter 11: Porous Polymers for Hydrogen Production -- 11.1 Introduction -- 11.1.1 Approaches Utilized for the Generation of Porous Polymers (PPs) -- 11.1.1.1 Infiltration -- 11.1.1.2 Layer-by-Layer Assembly (LbL) -- 11.1.1.3 Conventional Polymerization -- 11.1.1.4 Electrochemical Polymerization -- 11.1.1.5 Controlled/Living Polymerization (CLP) -- 11.1.1.6 Macromolecular Design -- 11.1.1.7 Self-assembly -- 11.1.1.8 Phase Separation -- 11.1.1.9 Solid and Liquid Templating -- 11.1.1.10 Foaming -- 11.2 Various Porous Polymers for H 2 Production -- 11.2.1 Photocatalysts Based on Conjugated Microporous Polymers -- 11.2.2 Conjugated Microporous Polymers -- 11.2.3 Porous Conjugated Polymer (PCP) -- 11.2.4 Membrane Reactor -- 11.2.5 Paper-Structured Catalyst with Porous Fiber-Network Microstructure -- 11.2.6 Porous Organic Polymers (POPs) -- 11.2.7 PEM Water Electrolysis -- 11.2.8 Microporous Inorganic Membranes -- 11.2.9 Hybrid Porous Solids for Hydrogen Evolution -- 11.3 Other Alternatives for Hydrogen Production -- 11.3.1 Metal-Organic Frameworks (MOFs) -- 11.3.2 Covalent Organic Frameworks. , 11.3.3 Photochemical Device.

Note: Intro -- Green Sustainable Process for Chemical and Environmental Engineering and Science: Green Inorganic Synthesis -- Copyright -- Contents -- Contributors -- Chapter 1: Microwave-assisted green synthesis of inorganic nanomaterials -- Description -- Key features -- 1. Introduction -- 2. Technical aspects of microwave technique -- 2.1. Principles and heating mechanism of microwave method -- 2.2. Green solvents for microwave reactions -- 2.3. Microwave versus conventional synthesis -- 2.4. Microwave instrumentation -- 2.5. Advantages and limitations -- 3. MW-assisted green synthesis of inorganic nanomaterials -- 3.1. Metallic nanostructured materials -- 3.2. Metal oxides nanostructured materials -- 3.3. Metal chalcogenides nanostructured materials -- 3.4. Quantum dot nanostructured materials -- 4. Conclusions and future aspects -- 4.1. Challenges and scope to further study -- References -- Chapter 2: Green synthesis of inorganic nanoparticles using microemulsion methods -- Description -- Key features -- 1. Introduction -- 2. Fundamental aspects of microemulsion synthesis -- 2.1. Microemulsion and types -- 2.2. Micelles, types, and formation mechanism -- 2.3. Hydrophilic-lipophilic balance number -- 2.4. Surfactants and types -- 2.5. Advantages and limitations of microemulsion synthesis of nanomaterials -- 3. Microemulsion-assisted green synthesis of inorganic nanostructured materials -- 3.1. General mechanism microemulsion method for nanomaterial synthesis -- 3.2. Preparation of metallic and bimetallic nanoparticles -- 3.3. Metal oxide synthesis by microemulsion -- 3.4. Synthesis of metal chalcogenide nanostructured materials -- 3.5. Synthesis of inorganic quantum dots -- 4. Conclusions, challenges, and scope to further study -- References -- Chapter 3: Synthesis of inorganic nanomaterials using microorganisms -- 1. Introduction. , 2. Green approach for synthesis of nanoparticles -- 3. General mechanisms of biosynthesis -- 4. Optimization of nanoparticles biosynthesis -- 4.1. Effect of the temperature -- 4.2. Effect of pH -- 4.3. Effect of metal precursor concentration -- 4.4. Effect of culture medium composition -- 4.5. Effect of biomass quantity and age -- 4.6. Synthesis time -- 5. Biosynthesis of metal oxide nanoparticles -- 5.1. Bacteria-mediated synthesis -- 5.2. Fungi-mediated synthesis -- 5.3. Yeast-mediated synthesis -- 5.4. Algae- and viruses-mediated synthesis -- 6. Biosynthesis of metal chalcogenide nanoparticles -- 7. Final considerations -- References -- Chapter 4: Challenge and perspectives for inorganic green synthesis pathways -- 1. Introduction -- 2. Synthesis methods -- 2.1. Physical synthesis -- 2.1.1. Advantages -- 2.1.2. Inconvenient -- 2.2. Chemical synthesis -- 2.2.1. Advantages -- 2.2.2. Inconvenient -- 2.3. Green synthesis of inorganic nanomaterials and application -- 3. Challenge and perspectives -- 4. Conclusion -- References -- Chapter 5: Synthesis of inorganic nanomaterials using carbohydrates -- 1. Introduction -- 1.1. Types of nanomaterials -- 1.2. Approaches for the synthesis of inorganic nanomaterials -- 1.3. Characterization of inorganic nanomaterials -- 1.4. What are carbohydrates? -- 1.4.1. Types of carbohydrates -- Monosaccharides -- Oligosaccharides -- Polysaccharides -- 2. Synthesis of inorganic nanomaterials using carbohydrates -- 2.1. Synthesis of metal nanomaterials using carbohydrates -- 2.2. Synthesis of metal oxide-based nanomaterials using carbohydrates -- 2.3. Synthesis of nanomaterials using polysaccharides extracted from fungi and plant -- 3. The advantages and disadvantages of inorganic nanomaterials -- 4. Conclusion and future scope -- References -- Chapter 6: Fundamentals for material and nanomaterial synthesis. , 1. Introduction -- 2. Fundamental synthesis for materials -- 2.1. Solid-state synthesis -- 2.2. Chemical vapor transport -- 2.3. Sol-gel process -- 2.4. Melt growth (MG) method -- 2.5. Chemical vapor deposition -- 2.6. Laser ablation methods -- 2.7. Sputtering method -- 2.8. Molecular beam epitaxy method -- 3. Fundamental synthesis for nanomaterials -- 3.1. Top-down and bottom-up approaches -- 3.1.1. Ball milling (BL) synthesis process -- 3.1.2. Electron beam lithography -- 3.1.3. Inert gas condensation synthesis method -- 3.1.4. Physical vapor deposition methods -- 3.1.5. Laser pyrolysis methods -- 3.2. Chemical synthesis methods -- 3.2.1. Sol-gel method -- 3.2.2. Chemical vapor deposition method -- 3.2.3. Hydrothermal synthesis -- 3.2.4. Polyol process -- 3.2.5. Microemulsion technique -- 3.2.6. Microwave-assisted (MA) synthesis -- 3.3. Bio-assisted (B-A) methods -- 4. Conclusion -- References -- Chapter 7: Bioinspired synthesis of inorganic nanomaterials -- 1. Introduction -- 1.1. Nanomaterials and current limitations -- 1.2. Bioinspired synthesis -- 2. General mechanism of interaction -- 3. Bioinspired synthesis of inorganic nanomaterials -- 3.1. Microorganisms-mediated synthesis -- 3.2. Plant-mediated synthesis -- 3.2.1. Root extract assisted synthesis -- 3.2.2. Leaves extract assisted synthesis -- 3.2.3. Shoot-mediated synthesis -- 3.3. Protein templated synthesis -- 3.4. DNA-templated synthesis -- 3.5. Butterfly wing scales-templated synthesis -- 4. Applications of bioinspired nanomaterials -- 5. Conclusions -- References -- Chapter 8: Polysaccharides for inorganic nanomaterials synthesis -- 1. Introduction -- 2. Polysaccharides -- 2.1. Types of polysaccharides -- 2.1.1. Cellulose -- 2.1.2. Starch -- 2.1.3. Chitin -- 2.1.4. Chitosan -- 2.1.5. Properties of polysaccharides for bioapplications -- 3. Nanomaterials -- 3.1. Types of nanomaterials. , 3.1.1. Organic nanomaterials -- Carbon nanotubes -- Graphene -- Fullerenes -- 3.1.2. Inorganic nanomaterials -- Magnetic nanoparticles -- Metal nanoparticles -- Metal oxide nanoparticles -- Luminescent inorganic nanoparticles -- 3.2. Health effects of nanomaterials -- 4. Polysaccharide-based nanomaterials -- 4.1. Cellulose nanomaterials -- 4.1.1. Preparation of cellulose nanomaterials -- 4.1.2. Structure of cellulose nanomaterials -- 4.2. Chitin nanomaterials -- 4.2.1. Preparation of chitin nanomaterials -- 4.2.2. Structure and properties of chitin nanomaterials -- 4.3. Starch nanomaterials -- 4.3.1. Preparation of starch nanomaterials -- 4.3.2. Structure and properties of starch nanomaterials -- 5. Preparation of polysaccharide-based inorganic nanomaterials -- 5.1. Bulk nanocomposites -- 5.2. Composite nanoparticles -- 6. Applications of polysaccharide-based inorganic nanomaterials -- 6.1. Biotechnological applications -- 6.1.1. Bioseparation -- 6.1.2. Biolabeling and biosensing -- 6.1.3. Antimicrobial applications -- 6.2. Biomedical applications -- 6.2.1. Drug delivery -- 6.2.2. Digital imaging -- 6.2.3. Cancer treatment -- 6.3. Agricultural applications -- 7. Characterization of polysaccharide-based nanomaterials -- 7.1. Spectroscopy -- 7.1.1. Infrared (IR) spectroscopy -- 7.1.2. Surface-enhanced Raman scattering (SERS) -- 7.1.3. UV-visible absorbance spectroscopy -- 7.2. Microscopy -- 7.2.1. Scanning electron microscopy (SEM) -- 7.2.2. Transmission electron microscopy (TEM) -- 7.3. X-ray methods -- 7.4. Thermal analysis -- 8. Future prospects -- 9. Concluding remarks -- References -- Chapter 9: Supercritical fluids for inorganic nanomaterials synthesis -- 1. Introduction -- 2. The supercritical fluid as a substitute technology -- 2.1. What is supercritical fluid? -- 2.2. Supercritical antisolvent precipitation. , 2.3. Supercritical-assisted atomization -- 2.4. Sol-gel drying method -- 3. Synthesis in supercritical fluids -- 3.1. Route of supercritical fluids containing nanomaterials synthesis -- 3.2. Sole supercritical fluid -- 3.3. Mixed supercritical fluid -- 4. Theory of the synthesis of supercritical fluids containing nanomaterials -- 4.1. Supercritical fluids working process -- 4.2. Origin of nanoparticles -- 4.3. The rapid expansion of supercritical solutions -- 5. Conclusion -- References -- Chapter 10: Green synthesized zinc oxide nanomaterials and its therapeutic applications -- 1. Introduction -- 2. Green synthesis -- 3. ZnO NPs characterization -- 4. ZnO NPs synthesis by plant extracts -- 5. ZnO NPs synthesis by bacteria and actinomycetes -- 6. ZnO NPs synthesis by algae -- 7. ZnO NPs synthesis by fungi -- 8. NPs synthesis by virus -- 9. ZnO NPs synthesis with alternative green sources -- 10. Therapeutic applications -- 11. Conclusions -- References -- Chapter 11: Sonochemical synthesis of inorganic nanomaterials -- 1. Background -- 2. Inorganic nanomaterials in sonochemical synthesis -- 3. Applications -- 4. Final comments -- References -- Index.

Note: Cover -- Title Page -- Copyright Page -- Contents -- Preface -- Chapter 1 Progress in Separators for Rechargeable Batteries -- 1.1 Separator Overview -- 1.2 Polymer Membrane -- 1.2.1 Polyolefin Separators -- 1.2.2 PVDF -- 1.2.3 PTFE -- 1.2.4 PU -- 1.2.5 PVA -- 1.2.6 Cellulose -- 1.2.7 Other Polymer -- 1.3 Non-Woven Fabric Separator -- 1.3.1 PET -- 1.3.2 PAN -- 1.3.3 PVDF -- 1.3.4 PTFE -- 1.3.5 PVA -- 1.3.6 PI -- 1.4 Polymer Electrolyte -- 1.5 Conclusions -- References -- Chapter 2 Pb Acid Batteries -- 2.1 History of Batteries -- 2.2 Primary Batteries -- 2.3 Secondary Batteries -- 2.4 Flow Batteries -- 2.4.1 All Vanadium Redox Flow Batteries (VRBs) -- 2.4.2 Zinc-Bromine Flow Cells -- 2.5 Lead-Acid Batteries -- 2.5.1 Early Applications of Lead-Acid Batteries -- 2.5.2 Comparison With Other Types of Secondary Batteries -- 2.5.3 Electrochemistry of Lead-Acid Batteries -- 2.5.4 Basic Components of Lead-Acid Cells -- 2.5.5 Types of Lead-Acid Batteries -- 2.5.6 Charging -- 2.5.7 Maintenance -- 2.5.8 Failure Modes -- List of Abbreviations -- References -- Chapter 3 Flexible Batteries -- 3.1 Introduction -- 3.2 Battery Types -- 3.2.1 Lead-Acid Battery -- 3.2.2 Nickel Cadmium -- 3.2.3 Nickel/Hydrogen and Nickle/Metal Hydride -- 3.2.4 Lithium-Ion Batteries -- 3.3 Storage Mechanism -- 3.3.1 Flexible Electrode -- 3.3.2 Carbon Base Flexible Electrodes -- 3.4 Graphene Base Flexible Batteries -- 3.5 Metal Oxide-Based Flexible Batteries -- 3.6 Fiber-Shape Designed Flexible Batteries -- 3.7 Natural Fiber Base Flexible Batteries -- 3.8 Flexible Electrolytes -- 3.9 Conclusion -- References -- Chapter 4 Polymer Electrolytes in Rechargeable Batteries -- 4.1 Introduction -- 4.2 Solid Electrolytes for Rechargeable Batteries -- 4.2.1 Solid Oxide Electrolytes -- 4.2.2 Sulfide Solid Electrolytes -- 4.2.3 Inorganic-Organic Hybrid Electrolytes. , 4.2.4 Solid Polymer Electrolytes in Rechargeable Batteries -- 4.3 Polymer-Based Electrolytes -- 4.4 Classification of Polymer-Based Electrolytes -- 4.4.1 Polymer-Salt Complexes -- 4.4.2 Plasticized Polymer Electrolytes -- 4.4.3 Rubbery Electrolytes -- 4.4.4 Solvent-Swollen Polymers -- 4.4.5 Polyelectrolytes -- 4.4.6 Gel Polymer Electrolytes -- 4.4.7 Composite Polymer Electrolytes (CPEs) -- 4.4.8 Ionic Liquid Incorporated Polymer/Gel Electrolytes -- 4.5 Conclusion and Future Prospects -- References -- Chapter 5 Advancement in Electrolytes for Rechargeable Batteries -- 5.1 Introduction -- 5.2 Aqueous Electrolytes -- 5.2.1 Lithium Nitrate -- 5.2.2 Saturated LiCl Electrolyte -- 5.2.3 Aqueous Sodium Salts -- 5.3 Non-Aqueous Electrolytes -- 5.4 Polymer Electrolytes -- 5.4.1 Solid Polymer Electrolytes (SPE) -- 5.4.2 Gel Polymer Electrolytes (GPE) -- 5.5 Ionic Liquids Electrolytes (ILE) -- 5.6 Hybrid Electrolytes -- 5.7 Conclusions -- Acknowledgements -- References -- Chapter 6 Fabrication Assembly Techniques for K-Ion Batteries -- 6.1 Introduction -- 6.2 Battery and Its Types -- 6.3 Ni-Cd Batteries -- 6.4 Li-Ion Batteries -- 6.5 Advantages of Rechargeable Batteries -- 6.6 Disadvantages of Rechargeable Batteries -- 6.7 K-Ion Batteries -- 6.8 Advantages -- 6.9 Disadvantages -- 6.10 Honeycomb Structure of K-Ion Batteries -- 6.10.1 Methods/Synthesis of Potassium Tellurates -- 6.11 Negative Electrode Materials for K-Ion Batteries -- 6.12 K-Ion Batteries Based on Patterned Electrodes -- 6.13 Conclusion -- Acknowledgement -- References -- Chapter 7 Recent Advances in Ni-Fe Batteries as Electrical Energy Storage Devices -- 7.1 Introduction -- 7.2 Structure of Ni-Fe Batteries -- 7.3 Discussion on Electrochemical Parameters of Various Materials for Ni-Fe Batteries -- 7.4 Conclusions -- References -- Chapter 8 Nickel-Metal Hydride (Ni-MH) Batteries -- 8.1 Introduction. , 8.2 History -- 8.3 Invention of the Rechargeable Battery -- 8.4 Metal Hydrides (MH) -- 8.5 Thermodynamics and Crystal Structures of Ni-MH Battery Materials -- 8.5.1 Thermodynamics -- 8.5.2 Crystal Structures of Battery Materials -- 8.5.3 Crystal Structure of AB -- 8.5.3 Crystal Structure of AB5 and AB2 Materials -- 8.5.4 Structure of AB5 Compounds -- 8.5.5 Structure of AB2 Compounds -- 8.5.6 Substitutions of A and B Components in AB5 and AB2 -- 8.5.7 Mg-Based Alloys -- 8.5.8 Rare Earth-Mg-Ni-Based Alloys -- 8.5.9 Ti-V-Based Alloys -- 8.6 Ni-MH Batteries -- 8.7 Mechanism of Ni-MH Batteries -- 8.7.1 Battery Description -- 8.7.2 Principle -- 8.7.3 Negative Electrode -- 8.7.4 Positive Electrode -- 8.7.5 Electrolyte -- 8.7.6 Separator -- 8.8 Materials -- 8.9 Charging Nickel-Based Batteries -- 8.9.1 Guidelines for Charging -- 8.10 Performance -- 8.11 Factors Affecting Life -- 8.11.1 Exposure to Elevated Temperatures -- 8.11.2 Reversal -- 8.11.3 Extended Storage under Load -- 8.11.4 Limiting Mechanisms -- 8.12 Advantages -- 8.13 Applications -- 8.13.1 Electric Vehicles -- 8.13.2 Fuel Cell (FC) EVs -- 8.13.3 Pure EVs -- 8.13.4 Hybrid EVs -- 8.13.5 Applications in Traditional Portable Electronic Devices -- 8.13.5.1 Mobile Phones -- 8.13.5.2 Digital Cameras -- 8.14 Recent Developments and Research Work -- 8.15 Shortcomings -- References -- Chapter 9 Ni-Cd Batteries -- 9.1 Introduction -- 9.2 History -- 9.3 Characteristics -- 9.4 Construction and Working -- 9.5 Types of NiCd Batteries -- 9.6 Memory Effect -- 9.7 Maintenance and Safety -- 9.8 Availability and Cost -- 9.9 Applications -- 9.9.1 Transportation in Hybrid and Electric Vehicles -- 9.9.2 Aircrafts -- 9.9.3 Electronic Flash Units -- 9.9.4 Cordless Applications -- 9.9.5 Motorized Equipment -- 9.9.6 Two Ways Radios -- 9.9.7 Medical Instrumentation -- 9.9.8 Toys -- 9.10 Advantages and Disadvantages. , 9.11 Recycling of NiCd Batteries -- 9.12 Comparison With Other Batteries -- 9.13 Conclusion -- Acknowledgement -- References -- Chapter 10 Ca-Ion Batteries -- 10.1 Introduction -- 10.2 Selection of Anodic and Cathodic Materials -- 10.2.1 Alloy Anodes -- 10.2.1.1 Choice of Cathodes for Calcium-Ion Batteries -- 10.2.1.2 Choice of Anodes for Calcium-Ion Batteries -- 10.3 Electrochemical Arrangement -- 10.4 Electrode Materials -- 10.5 Conclusions and Perspectives -- References -- Chapter 11 Analytical Investigations in Rechargeable Batteries -- 11.1 Introduction -- 11.2 Components of a Battery -- 11.3 Principle of Rechargeable Battery -- 11.4 Aging of Rechargeable Battery -- 11.5 Analysis Techniques Used for Rechargeable Batteries -- 11.5.1 X-Ray Based -- 11.5.2 Neutron Based -- 11.5.3 Optical Analysis Techniques -- 11.5.4 Electron Based -- 11.5.5 Vibrational Analysis Techniques -- 11.5.6 Magnetism Based -- 11.5.7 Gravimetric-Based Analysis Techniques -- 11.6 Conclusion -- References -- Chapter 12 Remediation of Spent Rechargeable Batteries -- 12.1 Introduction -- 12.2 A Brief History of Battery Origin -- 12.3 The Types of Batteries -- 12.3.1 Types of Primary Batteries -- 12.3.1.1 Types of Secondary Batteries -- 12.4 Recharge the Battery -- 12.5 Battery Life -- 12.6 A Lithium-Ion Battery (LIB) -- 12.6.1 Advantages of Li-Ion Batteries -- 12.6.2 Disadvantages of Li-Ion Batteries -- 12.7 Impact of Batteries on Health -- 12.7.1 Protection Against Battery Disadvantages [101] -- 12.8 Mercury (Hg) -- 12.9 Remediation of Spent Rechargeable Batteries -- 12.9.1 Future and Challenges: Nanotechnology in Batteries -- 12.10 Conclusions -- References -- Chapter 13 Classification, Modeling, and Requirements for Separators in Rechargeable Batteries -- Acronyms -- 13.1 Introduction and Area -- 13.2 Separators in Rechargeable Batteries. , 13.3 Classification of Separator in Rechargeable Batteries -- 13.3.1 Nonwoven Separators -- 13.3.2 Microporous Membrane Separators -- 13.3.3 Ion-Exchange Membrane Separators -- 13.3.4 Nanoporous Membrane Separators -- 13.4 Properties of Separator in Rechargeable Batteries -- 13.5 Requirements for Separator in Rechargeable Batteries -- 13.6 Modeling of Separator in Rechargeable Batteries -- 13.7 Results and Discussions -- 13.8 Future Approach -- 13.9 Conclusion -- References -- Chapter 14 Research and Development and Commercialization in Rechargeable Batteries -- 14.1 Introduction -- 14.1.1 Types of Rechargeable Batteries (RBs) and Challenges Faced Towards Practical Applications -- 14.1.1.1 Li-Ion Batteries (LIBs) -- 14.1.1.2 Na and K-Ion Batteries -- 14.1.1.3 Magnesium Rechargeable Batteries (MgRBs) -- 14.1.1.4 Aqueous RBs -- 14.1.1.5 Pb-Acid, Ni-Cd, and Ni-MH Batteries -- 14.1.1.6 Zinc-Ion RBs -- 14.1.1.7 Metal-Air Batteries -- 14.1.1.8 Flexible RBs -- 14.1.2 Nanotechnology Interventions in Rechargeable Batteries -- 14.2 Research and Development in Rechargeable Batteries -- 14.2.1 Zinc Rechargeable Batteries (ZnRBs) -- 14.2.2 Magnesium Rechargeable Batteries (MgRBs) -- 14.2.3 Aqueous RBs and Hybrid Aqueous RBs -- 14.2.4 Li-Based RBs -- 14.3 Commercialization Aspects of Rechargeable Batteries -- 14.4 Future Prospects of RBs -- 14.5 Conclusion -- References -- Chapter 15 Alkaline Batteries -- 15.1 Introduction -- 15.1.1 How Batteries Work -- 15.2 History -- 15.3 Advantages -- 15.4 Disadvantages -- 15.4.1 Internal Resistance -- 15.4.2 Leakage and Damages -- 15.5 Spent ARBs -- 15.6 Classification of ABs -- 15.6.1 Ni/Co Batteries -- 15.6.2 Ni/Ni ARBs -- 15.7 Application of ABs -- 15.8 Conclusion -- Acknowledgements -- References -- Chapter 16 Advances in "Green" Ion-Batteries Using Aqueous Electrolytes -- 16.1 Introduction. , 16.2 Monovalent Ion Aqueous Batteries.

Note: Cover -- Title Page -- Copyright Page -- Contents -- Preface -- Chapter 1 2D Metal-Organic Frameworks -- 1.1 Introduction -- 1.2 Synthesis Approaches -- 1.2.1 Selection of Synthetic Raw Materials -- 1.2.2 Solvent Volatility Method -- 1.2.3 Diffusion Method -- 1.2.3.1 Gas Phase Diffusion -- 1.2.3.2 Liquid Phase Diffusion -- 1.2.4 Sol-Gel Method -- 1.2.5 Hydrothermal/Solvothermal Synthesis Method -- 1.2.6 Stripping Method -- 1.2.7 Microwave Synthesis Method -- 1.2.8 Self-Assembly -- 1.2.9 Special Interface Synthesis Method -- 1.2.10 Surfactant-Assisted Synthesis Method -- 1.2.11 Ultrasonic Synthesis -- 1.3 Structures, Properties, and Applications -- 1.3.1 Structure and Properties of MOFs -- 1.3.2 Application in Biomedicine -- 1.3.3 Application in Gas Storage -- 1.3.4 Application in Sensors -- 1.3.5 Application in Chemical Separation -- 1.3.6 Application in Catalysis -- 1.3.7 Application in Gas Adsorption -- 1.4 Summary and Outlook -- Acknowledgements -- References -- Chapter 2 2D Black Phosphorus -- 2.1 Introduction -- 2.2 The Research on Black Phosphorus -- 2.2.1 The Structure and Properties -- 2.2.1.1 The Structure of Black Phosphorus -- 2.2.1.2 The Properties of Black Phosphorus -- 2.2.2 Preparation Methods -- 2.2.2.1 Mechanical Exfoliation -- 2.2.2.2 Liquid-Phase Exfoliation -- 2.2.3 Antioxidant -- 2.2.3.1 Degradation Mechanism -- 2.2.3.2 Adding Protective Layer -- 2.2.3.3 Chemical Modification -- 2.2.3.4 Doping -- 2.3 Applications of Black Phosphorus -- 2.3.1 Electronic and Optoelectronic -- 2.3.1.1 Field-Effect Transistors -- 2.3.1.2 Photodetector -- 2.3.2 Energy Storage and Conversion -- 2.3.2.1 Catalysis -- 2.3.2.2 Batteries -- 2.3.2.3 Supercapacitor -- 2.3.3 Biomedical -- 2.4 Conclusion and Outlook -- Acknowledgements -- References -- Chapter 3 2D Metal Carbides -- 3.1 Introduction -- 3.2 Synthesis Approaches -- 3.2.1 Ti3C2 Synthesis. , 3.2.2 V2C Synthesis -- 3.2.3 Ti2C Synthesis -- 3.2.4 Mo2C Synthesis -- 3.3 Structures, Properties, and Applications -- 3.3.1 Structures and Properties of 2D Metal Carbides -- 3.3.1.1 Structures and Properties of Ti3C2 -- 3.3.1.2 Structural Properties of Ti2C -- 3.3.1.3 Structural Properties of Mo2C -- 3.3.1.4 Structural Properties of V2C -- 3.3.2 Carbide Materials in Energy Storage Applications -- 3.3.2.1 Ti3C2 -- 3.3.2.2 Ti2C -- 3.3.2.3 V2C -- 3.3.2.4 Mo2C -- 3.3.3 Metal Carbide Materials in Catalysis Applications -- 3.3.3.1 Ti3C2 -- 3.3.3.2 V2C -- 3.3.3.3 Mo2C -- 3.3.4 Metal Carbide Materials in Environmental Management Applications -- 3.3.4.1 Ti3C2 in Environmental Management Applications -- 3.3.4.2 Ti2C in Environmental Management Applications -- 3.3.4.3 V2C in Environmental Management Applications -- 3.3.4.4 Mo2C in Environmental Management Applications -- 3.3.5 Carbide Materials in Biomedicine Applications -- 3.3.5.1 Ti3C2 in Biomedicine Applications -- 3.3.5.2 Ti2C in Biomedicine Applications -- 3.3.5.3 V2C in Biomedicine Applications -- 3.3.5.4 Mo2C in Biomedicine Applications -- 3.3.6 Carbide Materials in Gas Sensing Applications -- 3.3.6.1 Ti3C2 in Gas Sensing Applications -- 3.3.6.2 Ti2C in Gas Sensing Applications -- 3.3.6.3 V2C in Gas Sensing Applications -- 3.3.6.4 Mo2C in Gas Sensing Applications -- 3.4 Summary and Outlook -- Acknowledgements -- References -- Chapter 4 2D Carbon Materials as Photocatalysts -- 4.1 Introduction -- 4.2 Carbon Nanostructured-Based Materials -- 4.2.1 Forms of Carbon -- 4.2.2 Synthesis of Carbon Nanostructured-Based Materials -- 4.3 Photo-Degradation of Organic Pollutants -- 4.3.1 Graphene, Graphene Oxide, Graphene Nitride (g-C3N4) -- 4.3.1.1 Graphene-Based Materials -- 4.3.1.2 Graphene Nitride (g-C3N4) -- 4.3.2 Carbon Dots (CDs) -- 4.3.3 Carbon Spheres (CSs). , 4.4 Carbon-Based Materials for Hydrogen Production -- 4.5 Carbon-Based Materials for CO2 Reduction -- References -- Chapter 5 Sensitivity Analysis of Surface Plasmon Resonance Biosensor Based on Heterostructure of 2D BlueP/MoS2 and MXene -- 5.1 Introduction -- 5.2 Proposed SPR Sensor, Design Considerations, and Modeling -- 5.2.1 SPR Sensor and Its Sensing Principle -- 5.2.2 Design Consideration -- 5.2.2.1 Layer 1: Prism for Light Coupling -- 5.2.2.2 Layer 2: Metal Layer -- 5.2.2.3 Layer 3: BlueP/MoS2 Layer -- 5.2.2.4 Layer 4: MXene (Ti3C2Tx) Layer as BRE for Biosensing -- 5.2.2.5 Layer 5: Sensing Medium (RI-1.33-1.335) -- 5.2.3 Proposed Sensor Modeling -- 5.3 Results Discussion -- 5.3.1 Role of Monolayer BlueP/MoS2 and MXene (Ti3C2Tx) and Its Comparison With Conventional SPR -- 5.3.2 Influence of Varying Heterostructure Layers for Proposed Design -- 5.3.3 Effect of Changing Prism Material and Metal on Performance of Proposed Design -- 5.4 Conclusion -- References -- Chapter 6 2D Perovskite Materials and Their Device Applications -- 6.1 Introduction -- 6.2 Structure -- 6.2.1 Crystal Structure -- 6.2.2 Electronic Structure of 2D Perovskites -- 6.2.3 Structure of Photovoltaic Cell -- 6.3 Discussion and Applications -- 6.4 Conclusion -- References -- Chapter 7 Introduction and Significant Parameters for Layered Materials -- 7.1 Graphene -- 7.2 Phosphorene -- orthorhombic rhombohedral Simple cubic -- semiconductor semimetal metal -- 7.3 Silicene -- 7.4 ZnO -- 7.5 Transition Metal Dichalcogenides (TMDCs) -- 7.6 Germanene and Stanene -- 7.7 Heterostructures -- References -- Chapter 8 Increment in Photocatalytic Activity of g-C3N4 Coupled Sulphides and Oxides for Environmental Remediation -- 8.1 Introduction -- 8.2 GCN Coupled Metal Sulphide Heterojunctions for Environment Remediation -- 8.2.1 GCN and MoS2-Based Photocatalysts. , 8.2.2 GCN and CdS-Based Heterojunctions -- 8.2.3 Some Other GCN Coupled Metal Sulphide Photocatalysts -- 8.3 GCN Coupled Metal Oxide Heterojunctions for Environment Remediation -- 8.3.1 GCN and MoO3-Based Heterojunctions -- 8.3.2 GCN and Fe2O3-Based Heterojunctions -- 8.3.3 Some Other GCN Coupled Metal Oxide Photocatalysts -- 8.4 Conclusions and Outlook -- References -- Chapter 9 2D Zeolites -- 9.1 Introduction -- 9.1.1 What is 2D Zeolite? -- 9.1.2 Advancement in Zeolites to 2D Zeolite -- 9.2 Synthetic Method -- 9.2.1 Bottom-Up Method -- 9.2.2 Top-Down Method -- 9.2.3 Support-Assisted Method -- 9.2.4 Post-Synthesis Modification of 2D Zeolites -- 9.3 Properties -- 9.4 Applications -- 9.4.1 Petro-Chemistry -- 9.4.2 Biomass Conversion -- 9.4.2.1 Pyrolysis of Solid Biomass -- 9.4.2.2 Condensation Reactions -- 9.4.2.3 Isomerization -- 9.4.2.4 Dehydration Reactions -- 9.4.3 Oxidation Reactions -- 9.4.4 Fine Chemical Synthesis -- 9.4.5 Organometallics -- 9.5 Conclusion -- References -- Chapter 10 2D Hollow Nanomaterials -- 10.1 Introduction -- 10.2 Structural Aspects of HNMs -- 10.3 Synthetic Approaches -- 10.3.1 Template-Based Strategies -- 10.3.1.1 Hard Templating -- 10.3.1.2 Soft Templating -- 10.3.2 Self-Templating Strategies -- 10.3.2.1 Surface Protected Etching -- 10.3.2.2 Ostwald Ripening -- 10.3.2.3 Kirkendall Effect -- 10.3.2.4 Galvanic Replacement -- 10.4 Medical Applications of HNMs -- 10.4.1 Imaging and Diagnosis Applications -- 10.4.2 Applications of Nanotube Arrays -- 10.4.2.1 Pharmacy and Medicine -- 10.4.2.2 Cancer Therapy -- 10.4.2.3 Immuno and Hyperthermia Therapy -- 10.4.2.4 Infection Therapy and Gene Therapy -- 10.4.3 Hollow Nanomaterials in Diagnostics and Therapeutics -- 10.4.4 Applications in Regenerative Medicine -- 10.4.5 Anti-Neurodegenerative Applications -- 10.4.6 Photothermal Therapy -- 10.4.7 Biosensors. , 10.5 Non-Medical Applications of HNMs -- 10.5.1 Catalytic Micro or Nanoreactors -- 10.5.2 Energy Storage -- 10.5.2.1 Lithium Ion Battery -- 10.5.2.2 Supercapacitor -- 10.5.3 Nanosensors -- 10.5.4 Wastewater Treatment -- 10.6 Toxicity of 2D HNMs -- 10.7 Future Challenges -- 10.8 Conclusion -- Acknowledgement -- References -- Chapter 11 2D Layered Double Hydroxides -- 11.1 Introduction -- 11.2 Structural Aspects -- 11.3 Synthesis of LDHs -- 11.3.1 Co-Precipitation Method -- 11.3.2 Urea Hydrolysis -- 11.3.3 Ion-Exchange Method -- 11.3.4 Reconstruction Method -- 11.3.5 Hydrothermal Method -- 11.3.6 Sol-Gel Method -- 11.4 Nonmedical Applications of LDH -- 11.4.1 Adsorbent -- 11.4.2 Catalyst -- 11.4.3 Sensors -- 11.4.4 Electrode -- 11.4.5 Polymer Additive -- 11.4.6 Anion Scavenger -- 11.4.7 Flame Retardant -- 11.5 Biomedical Applications -- 11.5.1 Biosensors -- 11.5.2 Scaffolds -- 11.5.3 Anti-Microbial Agents -- 11.5.4 Drug Delivery -- 11.5.5 Imaging -- 11.5.6 Protein Purification -- 11.5.7 Gene Delivery -- 11.6 Toxicity -- 11.7 Conclusion -- Acknowledgement -- References -- Chapter 12 Experimental Techniques for Layered Materials -- 12.1 Introduction -- 12.2 Methods for Synthesis of Graphene Layered Materials -- 12.3 Selection of a Suitable Metallic Substrate -- 12.4 Graphene Synthesis by HFTCVD -- 12.5 Graphene Transfer -- 12.6 Characterization Techniques -- 12.6.1 X-Ray Diffraction Technique -- d D k -- 12.6.2 Field Emission Scanning Electron Microscopy (FESEM) -- 12.6.3 Transmission Electron Microscopy (TEM) -- 12.6.4 Fourier Transform Infrared Radiation (FTIR) -- 12.6.5 UV-Visible Spectroscopy -- 12.6.6 Raman Spectroscopy -- 12.6.7 Low Energy Electron Microscopy (LEEM) -- 12.7 Potential Applications of Graphene and Derived Materials -- 12.8 Conclusion -- Acknowledgement -- References -- Chapter 13 Two-Dimensional Hexagonal Boron Nitride and Borophenes. , 13.1 Two-Dimensional Hexagonal Boron Nitride (2D h-BN): An Introduction.

Note: Cover -- Half-Title Page -- Series Page -- Title Page -- Copyright Page -- Contents -- Preface -- 1 Toxic Geogenic Contaminants in Serpentinitic Geological Systems: Occurrence, Behavior, Exposure Pathways, and Human Health Risks -- 1.1 Introduction -- 1.2 Serpentinitic Geological Systems -- 1.2.1 Nature, Occurrence, and Geochemistry -- 1.2.2 Occurrence and Behavior of Toxic Contaminants -- 1.3 Human Exposure Pathways -- 1.3.1 Occupational Exposure -- 1.3.2 Non-Occupational Exposure Routes -- 1.4 Human Health Risks and Their Mitigation -- 1.4.1 Health Risks -- 1.4.2 Mitigating Human Exposure and Health Risks -- 1.5 Future Perspectives -- 1.6 Conclusions -- Acknowledgements -- References -- 2 Benefits of Geochemistry and Its Impact on Human Health -- 2.1 Introduction -- 2.2 General Overview of Geochemistry and Human Health -- 2.2.1 Types of Geochemistry -- 2.2.2 Some Beneficial Effect of Some Mineral With Health Benefits -- 2.2.3 Application of Geochemistry on Human Health -- 2.3 Conclusion and Recommendations -- References -- 3 Applications of Geochemistry in Livestock: Health and Nutritional Perspective -- 3.1 Introduction -- 3.2 General and Global Perspective About Geochemistry in Livestock -- 3.3 Types of Geochemistry and Their Numerous Benefits -- 3.3.1 Analytical Geochemistry -- 3.3.2 Isotope Geochemistry -- 3.3.3 Low Temperature Geochemistry -- 3.3.4 Organic and Petroleum Geochemistry -- 3.4 Application of Geochemistry in Livestock -- 3.5 Geochemistry and Animal Health -- 3.6 General Overview of Geochemistry in Livestock's Merits of Geochemistry/Essential Minerals in Livestocks -- 3.6.1 Specific Examples of Authors That Have Used Essential Minerals in Livestock -- 3.6.2 Livestock in Relation to Geominerals -- 3.6.3 Trace Minerals Parallel Importance in Livestock -- 3.6.4 Heavy Metals Impact Livestock -- 3.7 Conclusion and Recommendations. , References -- 4 Application in Geochemistry Toward the Achievement of a Sustainable Agricultural Science -- 4.1 Introduction -- 4.2 General Overview on the Utilization of Geochemistry and Their Wide Application on Agriculture -- 4.2.1 Classification -- 4.2.2 Chemical Composition of Rocks -- 4.2.3 Effect of Some Beneficial Minerals in Agriculture -- 4.2.4 Beneficial Mineral Nutrients That are Crucial to the Development of Plants -- 4.3 Role of Geochemistry in Agriculture -- 4.4 Geochemical Effects of Heavy Metals on Crops Health -- 4.5 Conclusion and Recommendations -- References -- 5 Geochemistry, Extent of Pollution, and Ecological Impact of Heavy Metal Pollutants in Soil -- 5.1 Introduction -- 5.2 Material and Methods -- 5.2.1 Review Process -- 5.2.2 Ecological Risk Index -- 5.3 Toxic Heavy Metal and Their Impact to the Ecosystems -- 5.3.1 Arsenic -- 5.3.2 Cadmium -- 5.3.3 Chromium -- 5.3.4 Copper -- 5.3.5 Lead -- 5.3.6 Nickel -- 5.3.7 Zinc -- 5.4 Metal Pollution in Soil Across the Globe -- 5.5 Ecological and Human Health Risk Impacts of Heavy Metals -- 5.6 Conclusion -- References -- 6 Isotope Geochemistry -- 6.1 Introduction -- 6.2 Basic Definitions -- 6.2.1 The Notation -- 6.2.2 The Fractionation Factor -- 6.2.3 Isotope Fractionation -- 6.2.4 Mass Dependent and Independent Fractionations -- 6.3 Application of Traditional Isotopes in Geochemistry -- 6.3.1 Geothermometer -- 6.3.2 Isotopes in Biological System -- 6.3.3 Isotopes in Archaeology -- 6.3.4 Isotopes in Fossils and the Earliest Life -- 6.3.5 Isotopes in Hydrothermal and Ore Deposits -- 6.4 Non-Traditional Isotopes in Geochemistry -- 6.4.1 Application in Tracing of Source -- 6.4.2 Application in Process Tracing -- 6.4.3 Biological Cycling -- 6.5 Conclusion -- References -- 7 Environmental Geochemistry -- 7.1 Introduction -- 7.2 Overview of the Environmental Geochemistry -- 7.3 Conclusions. , 7.4 Abbreviations -- Acknowledgment -- References -- 8 Medical Geochemistry -- 8.1 Introduction -- 8.2 The Evolution of Geochemistry -- 8.3 This Science has Expanded Considerably to Become Distinct Branches -- 8.3.1 Cosmochemistry -- 8.3.2 The Economic Importance of Geochemistry -- 8.3.3 Analytical Geochemistry -- 8.3.4 Geochemistry of Radioisotopes -- 8.3.5 Medical Geochemistry and Human Health -- 8.3.6 Environmental Health and Safety -- 8.4 Conclusion -- References -- 9 Inorganic Geochemistry -- 9.1 Introduction -- 9.2 Elements and the Earth -- 9.2.1 Iron -- 9.2.2 Oxygen -- 9.2.3 Silicon -- 9.2.4 Magnesium -- 9.3 Geological Minerals -- 9.3.1 Quartz -- 9.3.2 Feldspar -- 9.3.3 Amphibole -- 9.3.4 Pyroxene -- 9.3.5 Olivine -- 9.3.6 Clay Minerals -- 9.3.7 Kaolinite -- 9.3.8 Bentonite, Montmorillonite, Vermiculite, and Biotite -- 9.4 Characterization Techniques -- 9.4.1 Powder X-Ray Diffraction -- 9.4.2 X-Ray Fluorescence Spectra -- 9.4.3 X-Ray Photoelectron Spectra -- 9.4.4 Electron Probe Micro-Analysis -- 9.4.5 Inductively Coupled Plasma Spectrometry -- 9.4.6 Fourier Transform Infrared Spectroscopy -- 9.4.7 Scanning Electron Microscopy Analysis -- 9.4.8 Energy Dispersive X-Ray Analysis -- 9.5 Conclusion -- References -- 10 Introduction and Scope of Geochemistry -- 10.1 Introduction -- 10.1.1 Periodic Table and Electronic Configuration -- 10.2 Periodic Properties -- 10.2.1 Ionization Enthalpy -- 10.2.2 Electron Affinity -- 10.2.3 Electro-Negativity -- 10.3 Chemical Bonding -- 10.3.1 Ionic Bond -- 10.3.2 Covalent Bond -- 10.3.3 Metallic Bond -- 10.3.4 Hydrogen Bond -- 10.3.5 Van der Waals Forces -- 10.4 Geochemical Classification and Distribution of Elements -- 10.4.1 Lithophiles -- 10.4.2 Siderophiles -- 10.4.3 Chalcophiles -- 10.4.4 Atmophiles -- 10.4.5 Biophiles -- 10.5 Chemical Composition of the Earth -- 10.6 Classification of Earth's Layers. , 10.6.1 Based on Chemical Composition -- 10.6.2 Based on Physical Properties -- 10.7 Spheres of the Earth -- 10.7.1 Geosphere/Lithosphere -- 10.7.2 Hydrosphere -- 10.7.3 Biosphere -- 10.7.4 Atmosphere -- 10.7.5 Troposphere -- 10.7.6 Stratosphere -- 10.7.7 Mesosphere -- 10.7.8 Thermosphere and Ionosphere -- 10.7.9 Exosphere -- 10.8 Sub-Disciplines of Geochemistry -- 10.9 Scope of Geochemistry -- 10.10 Conclusion -- References -- Index -- EULA.