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 -- Preface -- Contents -- 1 Green Approach: Microbes for Removal of Dyes and Metals via Ion Binding -- Abstract -- 1.1 Introduction -- 1.2 Pollutants in the Environment -- 1.2.1 Toxic Metals -- 1.2.2 Triphenylmethane Dyes -- 1.3 Bioremediation Approaches in Removing Pollutants -- 1.3.1 Non-microbial Strategies -- 1.3.2 Microbial-Based Strategies -- 1.4 Mechanisms for Removal of Pollutant Ions -- 1.4.1 Mechanisms for Removal of Metal Ions -- 1.4.2 Mechanisms for Removal of Dyes -- 1.5 Innovations in the Removal of Pollutant Ions -- 1.6 Conclusions and Future Prospects -- Acknowledgements -- References -- 2 Removal of Heavy Metal from Wastewater Using Ion Exchange Membranes -- Abstract -- 2.1 Introduction -- 2.2 Heavy Metal -- 2.2.1 Chromium -- 2.2.2 Nickel -- 2.2.3 Copper -- 2.2.4 Zinc -- 2.2.5 Cadmium -- 2.2.6 Mercury -- 2.2.7 Lead -- 2.3 Physical Treatment Methods -- 2.3.1 Ultrafiltration -- 2.3.2 Nanofiltration -- 2.3.3 Reverse Osmosis -- 2.3.4 Forward Osmosis -- 2.3.5 Adsorption -- 2.4 Chemical Treatment Methods -- 2.4.1 Electrodialysis Method -- 2.4.2 Fuel Cell Method -- 2.5 Remaining Challenges and Perspectives -- 2.6 Conclusion -- Acknowledgements -- References -- 3 Separation and Purification of Uncharged Molecules -- Abstract -- 3.1 Introduction -- 3.2 Separation and Purification of Vitamin B12 -- 3.2.1 Downstream Processing of Vitamin B12 for Measurement -- 3.3 Separation and Purification of Haemoglobin -- 3.4 Separation and Purification of Uncharged Dyes -- 3.4.1 Purification and Separation of Dyes -- 3.5 Conclusion -- References -- 4 Aluminosilicate Inorganic Polymers (Geopolymers): Emerging Ion Exchangers for Removal of Metal Ions -- Abstract -- 4.1 Introduction -- 4.2 Methodology and Calculations -- 4.2.1 Terminology: Ion Exchange or Adsorption -- 4.2.2 Evidence for Ion Exchange. , 4.2.3 Modeling of Adsorption of Metal Ions on Geopolymers -- 4.2.4 Geopolymer Preparation -- 4.2.5 Washing of the Geopolymeric Adsorbent -- 4.2.6 Comparison Between Geopolymers and Zeolites -- 4.2.7 Geopolymers as Ion Exchangers -- 4.2.7.1 Geopolymers as Ion Exchangers for Alkali Metal Ions -- 4.2.7.2 Geopolymers as Ion Exchangers for Ammonium Ion -- 4.2.7.3 Geopolymers as Ion Exchangers for Alkaline Earth Metals -- 4.2.7.4 Geopolymers as Ion Exchangers for Heavy Metals -- Metakaolin-Based Geopolymers -- Fly Ash-Based Geopolymers -- Zeolite-Based Geopolymers -- 4.2.7.5 Geopolymers as Ion Exchangers/Adsorbents for Cationic Organic Dyes -- 4.2.8 Comparison of Geopolymers with Zeolites -- 4.2.8.1 Synthesis Conditions -- 4.2.8.2 Crystallinity -- 4.2.8.3 Surface Area and Porosity -- 4.2.8.4 Cation Exchange Capacity -- 4.2.8.5 Selectivity for Metal Ions -- 4.2.8.6 Stability in Acidic Solutions -- 4.2.8.7 Thermal Stability -- 4.2.8.8 Mechanical Strength -- 4.2.8.9 Regeneration -- 4.2.9 Stabilization/Solidification/Encapsulation of Ion Exchangers in Geopolymers -- 4.3 Concluding Remarks -- References -- 5 Microwave-Assisted Hydrothermal Synthesis of Agglomerated Spherical Zirconium Phosphate for Removal of Cs+ and Sr2+ Ions from Aqueous System -- Abstract -- 5.1 Introduction -- 5.2 Materials and Methods -- 5.2.1 Preparation of Agglomerated Spherical Zirconium Phosphate -- 5.2.2 Characterization -- 5.2.3 Ion Exchange Properties -- 5.2.4 Elution Behaviour -- 5.2.5 Distribution Studies -- 5.3 Results and Discussion -- 5.3.1 Fourier-Transform Infrared (FT-IR) Characterization -- 5.3.2 Powder X-ray Diffraction Studies -- 5.3.3 Scanning Electron Microscopy (SEM) and Energy Dispersive (EDS) Characterization -- 5.3.4 Zeta and Surface Area Analysis -- 5.3.5 Ion Exchange Characteristics -- 5.3.6 Mechanism of Sr2+ Interaction with Zirconium Phosphate -- 5.4 Conclusion. , Acknowledgements -- References -- 6 Metal Hexacyanoferrates: Ion Insertion (or Exchange) Capabilities -- Abstract -- 6.1 Introduction -- 6.2 Ion Exchange -- 6.2.1 Ion Exchange in MHCF at Work: Potentiometric Ion Sensors -- 6.2.2 An Ion Exchange-Based Approach for the Recovery of Metal Ions: The Case of Cesium and Thallium -- 6.2.3 Electrochemically Driven Ion Exchange -- 6.2.4 Reversible Ion Insertion in Battery Systems -- 6.3 Conclusion -- References -- 7 Biosorbents and Composite Cation Exchanger for the Treatment of Heavy Metals -- Abstract -- 7.1 Introduction -- 7.2 Agro-Based Biosorbents for Heavy Metal Removal -- 7.3 Biopolymers -- 7.3.1 Functional Groups -- 7.3.2 Cellulose -- 7.3.3 Chitosan -- 7.3.4 Nanofiber Membranes and Packed-Bed Adsorbers -- 7.4 Composite Ion Exchangers -- 7.5 Conclusion and Future Outlook -- References -- 8 Rare Earth Elements-Separation Methods Yesterday and Today -- Abstract -- 8.1 Introduction -- 8.2 Rare Earth Elements -- 8.2.1 General Characteristics -- 8.2.2 The Occurrence of Rare Earth Elements -- 8.2.3 Physicochemical Properties of Rare Earth Elements -- 8.2.4 Application of Rare Earth Metals -- 8.2.5 Production and Consumption of Rare Earth Elements in the World -- 8.3 Rare Earth Element Recovery from Nickel-Metal Hydride Batteries -- 8.4 Rare Earth Element Recovery from Permanent Magnets -- 8.5 Separation of High-Purity Rare Earth Elements -- 8.5.1 Separations of Rare Earth Elements of High Purity Using Cation Exchangers -- 8.5.2 Separations of Rare Earth Elements of High Purity Using Anion Exchangers -- 8.5.3 Separations of Rare Earth Elements of High Purity Using Chelating Ion Exchangers -- 8.6 Current Technologies -- 8.7 Conclusions -- References -- 9 Sequestration of Heavy Metals from Industrial Wastewater Using Composite Ion Exchangers -- Abstract -- 9.1 Introduction -- 9.2 Ion-Exchange Materials. , 9.2.1 Organic Materials -- 9.2.2 Inorganic Materials -- 9.2.3 Composite Materials -- 9.2.3.1 Hybrid Materials -- 9.2.3.2 Nanocomposite -- 9.3 Mechanism of Ion-Exchange Process -- 9.4 Conclusion -- Acknowledgements -- References -- 10 Applications of Organic Ion Exchange Resins in Water Treatment -- Abstract -- 10.1 Introduction -- 10.2 Removal of Heavy Metals -- 10.3 Removal of Organics -- 10.3.1 Natural Organic Matter (NOM) -- 10.3.2 Disinfection by-Products (DBPs) -- 10.3.3 Surfactants -- 10.3.4 Pharmaceuticals -- 10.3.5 Dyes -- 10.3.6 Small Organic Matter -- 10.4 Desalination -- 10.5 Boron Removal -- 10.6 Removal of Anions -- 10.7 Removal of Cations -- 10.7.1 Hardness -- 10.7.2 Ammonium -- 10.8 Conclusions -- References.

Note: Intro -- Preface -- Contents -- Contributors -- Chapter 1: Role of Nano-photocatalysis in Heavy Metal Detoxification -- 1.1 Introduction -- 1.2 Heavy Metals and Their Toxicological Effects -- 1.2.1 Cadmium -- 1.2.2 Chromium -- 1.2.3 Copper -- 1.2.4 Lead -- 1.2.5 Mercury -- 1.2.6 Nickel -- 1.2.7 Zinc -- 1.3 Overview of Photocatalysis -- 1.4 Mechanism of Photocatalysis -- 1.5 Types of Photocatalysis -- 1.5.1 Homogeneous Photocatalysis -- 1.5.2 Heterogeneous Photocatalysis -- 1.6 Overview and Mechanism of Nano-photocatalysis -- 1.7 Photocatalytic Nanoparticle Synthesis -- 1.7.1 Organic Synthesis -- 1.7.1.1 Plant Extracts Aqueous Solutions -- 1.7.1.2 Microorganisms -- 1.7.2 Chemical Synthesis -- 1.7.2.1 Sol-Gel Method -- 1.7.2.2 Hydrothermal Method -- 1.7.2.3 Polyol Synthesis -- 1.7.2.4 Precipitation Method -- 1.7.3 Physical Synthesis -- 1.7.3.1 Ball Milling -- 1.7.3.2 Melt Mixing -- 1.7.3.3 Physical Vapour Deposition (PVD) -- 1.7.3.4 Laser Ablation -- 1.7.3.5 Sputter Deposition -- 1.8 Mode of Operation on Nano-photocatalysis -- 1.9 Parameters Affecting the Photocatalytic Efficiency -- 1.9.1 Effect of pH of the Reaction Solution -- 1.9.2 Effect of Photocatalyst Concentration -- 1.9.3 Effect of Substrate Adsorption -- 1.9.4 Effect of Dissolved Oxygen -- 1.10 Application -- 1.10.1 Chromium -- 1.10.1.1 pH -- 1.10.1.2 Light Intensity -- 1.10.1.3 Photocatalyst Dosage -- 1.10.1.4 Presence of Organic Compounds -- 1.10.2 Mercury -- 1.10.3 Arsenic -- 1.10.4 Uranium -- 1.11 Disadvantages of Photocatalysis -- 1.12 Photocatalyst Modifications -- 1.12.1 Dye Sensitization -- 1.12.2 Ion Doping -- 1.12.3 Composite Semiconductor -- 1.13 Conclusion -- References -- Chapter 2: Solar Photocatalysis Applications to Antibiotic Degradation in Aquatic Systems -- 2.1 Introduction -- 2.2 Solar Photocatalysis Process. , 2.3 Solar Photocatalysis Treatment for Antibiotic Degradation -- 2.3.1 Trimethoprim -- 2.3.2 Sulfamethoxazole -- 2.3.3 Erythromycin -- 2.3.4 Ciprofloxacin -- 2.4 Conclusions -- References -- Chapter 3: Biomass-Based Photocatalysts for Environmental Applications -- 3.1 Introduction -- 3.2 Background of Biomass-Derived Carbon -- 3.2.1 Biochar -- 3.2.2 Activated Carbon (AC) -- 3.3 Synthesis Methods of Biomass-Derived Carbon -- 3.3.1 Pyrolysis -- 3.3.2 Hydrothermal Carbonization -- 3.3.3 Physical and Chemical Activation -- 3.4 Photocatalysts and Photocatalysis Reactions -- 3.5 Functionalized AC and Applications -- 3.5.1 Types of Functionalized AC -- 3.5.2 Functionalized AC Photocatalysts and Its Application -- 3.6 Future Challenges and Conclusions -- References -- Chapter 4: Application of Bismuth-Based Photocatalysts in Environmental Protection -- 4.1 Introduction -- 4.2 Photocatalytic Oxidation of Pharmaceuticals in Water -- 4.2.1 Tetracycline -- 4.2.2 Ciprofloxacin and Other Antibiotics -- 4.2.3 Carbamazepine -- 4.2.4 Ibuprofen and Diclofenac -- 4.2.5 Other Pharmaceuticals -- 4.3 Photocatalytic Oxidation of Industrial Micropollutants -- 4.3.1 Bisphenol A -- 4.3.2 Oxidation of Other Industrial Pollutants -- 4.4 Oxidation of the Indoor Air Pollutant NOx -- 4.5 Photocatalytic Reduction of Pollutants in Water and Air -- 4.5.1 Reduction of Cr(VI) in Water -- 4.5.2 Reduction of CO2 in Air -- 4.6 Water Splitting -- 4.7 Conclusions -- References -- Chapter 5: Phosphors-Based Photocatalysts for Wastewater Treatment -- 5.1 Introduction -- 5.2 Phosphor Materials: A Historical Background -- 5.3 Inorganic Phosphors in Photocatalysis -- 5.3.1 Types of Inorganic Phosphor Materials -- 5.3.2 Down-Conversion Phosphors in Photocatalysis -- 5.3.3 Up-Conversion Phosphors in Photocatalysis -- 5.3.4 Long-Persistent Phosphors in Photocatalysis. , 5.4 Organic Up-Conversion Phosphors in Photocatalysis -- References -- Chapter 6: Nanocarbons-Supported and Polymers-Supported Titanium Dioxide Nanostructures as Efficient Photocatalysts for Remedi... -- 6.1 Introduction -- 6.1.1 Heterogeneous Semiconductor Photocatalysis -- 6.1.2 Potential TiO2-Based Photocatalysts -- 6.1.3 Limitations of the Fine Powder Form of TiO2-Based Photocatalysts -- 6.1.3.1 Comparison of Synthesis Methods -- 6.1.3.2 Improvements in TiO2 Performance by Structural Change, Doping, and Hybridization -- 6.2 TiO2 Photocatalysts with Polymer-Based Hybrid Photocatalysts for Wastewater Treatment -- 6.2.1 Need for Immobilization of TiO2-Based Photocatalysts -- 6.2.1.1 Features of a Stable Substrate, and Available Substrates -- 6.2.1.2 Comparison of Polymeric Supports for Wastewater Treatment -- 6.3 TiO2 Photocatalysts Supported with Nanocarbons for Wastewater Treatment -- 6.3.1 TiO2-Functionalized Nanocarbon-Based Photocatalysts -- 6.3.1.1 Potential Photocatalytic Improvements with Carbon Nanostructures for Wastewater Treatment -- 6.4 Conclusions and Future Outlook -- References -- Chapter 7: Investigation in Sono-photocatalysis Process Using Doped Catalyst and Ferrite Nanoparticles for Wastewater Treatment -- 7.1 Introduction -- 7.2 Dependency of Catalytic Activity -- 7.2.1 Size-Dependent Catalytic Activity -- 7.2.2 Shape-Dependent Catalytic Effect -- 7.2.3 Interparticle Distance-Dependent Catalytic Effect -- 7.2.4 Support Interaction and Charge Transfer-Dependent Reactivity -- 7.3 Type of Nanoparticles -- 7.3.1 Non-metallic Nanoparticles -- 7.3.2 Metallic Nanoparticles -- 7.3.3 Semiconductor Nanoparticles -- 7.3.4 Ceramic Nanoparticles -- 7.3.5 Polymer Nanoparticles -- 7.3.6 Lipid-Based Nanoparticles -- 7.4 Types of Nanoparticles Based on Structure -- 7.5 Synthesis and Applications -- 7.5.1 Discussions -- 7.6 Synergetic Effect. , 7.7 Conclusion and Overview -- References -- Chapter 8: Magnetic-Based Photocatalyst for Antibacterial Application and Catalytic Performance -- 8.1 Introduction -- 8.2 Magnetic-Based Photocatalysts in Inactivation of the Microorganism -- 8.3 Factors Affecting the Photocatalytic Bacterial Inactivation -- 8.3.1 Effect of Magnetic-Based Photocatalyst Concentration and Light Intensity -- 8.3.2 Nature of Microorganism -- 8.3.3 Solution pH of Magnetic-Based Photocatalyst Suspension -- 8.3.4 Initial Bacterial Concentration -- 8.3.5 Physiological State of Bacteria -- 8.4 Proposed Mechanism for Bacteria Disinfection by the Magnetic-Based Photocatalyst -- 8.5 Using Magnetic-Based Catalyst in Photocatalytic Abatement of Organics -- 8.6 Photocatalysis for the Simultaneous Treatment of Bacteria and Organics -- 8.7 Conclusion and Future Prospects -- References -- Chapter 9: Antimicrobial Activities of Photocatalysts for Water Disinfection -- 9.1 Introduction -- 9.2 Mechanisms of Photocatalytic Disinfection -- 9.3 Pure and Modified Photocatalysts -- 9.4 Photocatalytic Films and Biofilms -- 9.5 Photocatalytic Composites and Nanocomposites -- 9.6 Materials with Antimicrobial Activity in the Absence of Light -- 9.7 Case Study: Application of Supported Photocatalysts in Disinfection of Whey-Processing Water -- 9.8 Final Considerations -- References -- Chapter 10: Medicinal Applications of Photocatalysts -- 10.1 Introduction -- 10.1.1 Background -- 10.2 Antifungal Activity -- 10.3 Virucidal Activity -- 10.4 Antimicrobial Activity -- 10.5 Anticancer Activity -- 10.6 Conclusion -- References -- Index.

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 -- Preface -- Acknowledgements -- Contents -- Contributors -- Chapter-1 -- Saving Solvents in Chromatographic Purifications: The Counter-Current Chromatography Technique -- 1.1 Introduction -- 1.2 CCC Theory -- 1.2.1 High Loadability -- 1.2.2 Scale up Capability -- 1.3 Instrumentation -- 1.3.1 Hydrostatic and Hydrodynamic Instruments -- 1.3.2 Liquid Systems -- 1.4 Counter Current Chromatography, a Green Process -- 1.4.1 Saving Solvents -- 1.4.2 Improving Process Parameters -- 1.4.3 Injecting Crude Samples -- 1.4.4 Greener Solvents -- 1.5 Counter Current Chromatography, a Tool for Green Chemistry Development -- 1.5.1 Natural Products -- 1.5.2 Solute Partition Coefficient Determination -- 1.6 Conclusion -- References -- Chapter-2 -- Ion Size Exclusion Chromatohtaphy on Hypercrosslinked Polystyrene Sorbents as a Green Technology of Separating Mineral Elecyrolites -- 2.1 Introduction -- 2.2 Nanoporous Hypercrosslinked Polystyrene Sorbents -- 2.3 Brief Description of Chromatographic Experiments -- 2.4 Dimensions of Hydrated Ions -- 2.5 Separation of Electrolytes on Nanoporous Hypercrosslinked Sorbents -- 2.6 Basic Features of Size Exclusion Chromatography -- 2.7 Conception of "Ideal Separation Process" -- 2.8 Selectivity of Electrolyte Separation Process -- 2.9 Influence of the Electrolyte Concentration on the Selectivity of Separat -- 2.10 "Acid Retardation", "Base Retardation" and "Salt Retardation" Phenomena -- 2.11 Other Convincing Proofs of Separating Electrolytes via Exclusion Mechanism -- 2.12 Do we Really Need Sorbent Functional Groups to Separate Electrolytes? -- 2.13 Productivity of the Ion Size Exclusion Process -- 2.14 Ion Size Exclusion-Green Technology -- 2.15 Conclusion -- References -- Chapter-3 -- Supercritical Fluid Chromatography: A Green Approach for Separation and Purification of Organic and Inorganic Analytes. , 3.1 Introduction to Green Chemistry and Supercritical Fluid Chromatography -- 3.2 Super Critical Fluids -- 3.2.1 Supercritical Fluid Extraction (SFE) -- 3.3 Supercritical Fluid Chromatography (SFC): An Overview -- 3.3.1 History of Development of Supercritical Fluid Chromatography -- 3.3.2 Instrumentation -- 3.3.2.1 Advantages and Disadvantages of Supercritical Fluid Chromatography -- 3.3.3 Properties of SFC compared to GC and HPLC -- 3.4 Industrial Applications of SCFs and SFCs -- 3.5 Conclusion -- References -- Chapter-4 -- High Performance Thin-Layer Chromatography -- 4.1 Introduction -- 4.2 High Performance Thin-Layer Chromatography -- 4.3 Sample Preparation in HPTLC -- 4.4 Green Separation Modalities in HPTLC -- 4.4.1 "Three R" Philosophy-Replacement of Toxic Solvents with Environmental Friendly Mobi -- 4.4.1.1 Reversed-Phase Chromatography -- 4.4.1.2 Hydrophilic Interaction Chromatography (HILIC) in HPTLC -- 4.4.1.3 Salting-Out Chromatography in HPTLC -- 4.5 Conclusion -- References -- Chapter-5 -- Green Techniques in Gas Chromatography -- 5.1 Introduction -- 5.2 Sample Preparation -- 5.2.1 Direct Methods Without Sample Preparation -- 5.2.2 Solventless Sample Preparation Techniques -- 5.2.2.1 Solid Phase Extraction -- 5.2.2.2 Vapor-Phase Extraction -- 5.2.2.3 Thermal Desorption (TD)/Thermal Extraction (TE) -- 5.2.2.4 Membrane Extraction -- 5.2.3 Sample Preparation Using Environmentally Friendly Solvents -- 5.2.3.1 Supercritical Fluid Extraction (SFE) -- 5.2.3.2 Subcritical Water Extraction (SWE) -- 5.2.3.3 Ionic Liquids (ILs) -- 5.2.3.4 Cloud-Point Extraction -- 5.2.4 Assisted Solvent Extraction -- 5.3 Column Considerations for Green Gas Chromatography -- 5.4 Carrier Gas Considerations for Green Gas Chromatography -- 5.5 Coupling GC with Other Analytical Tools -- 5.6 On-Site Analysis. , 5.7 Conclusion -- References -- Chapter-6 -- Preparation and Purification of Garlic-Derived Organosulfur Compound Allicin by Green Methodologies -- 6.1 Introduction -- 6.2 Green RP-HPLC Purification of the Allicin -- 6.3 Characterization of the Allicin by Green Methodologies -- 6.4 Allicin in Different Garlic Extract by Green RP-HPLC -- 6.5 Allicin Green Chemical Synthesis -- 6.6 Stability of Allicin -- 6.7 Conclusions -- References -- Chapter-7 -- Green Sample Preparation Focusing on Organic Analytes in Complex Matrices -- 7.1 Introduction -- 7.1.1 Trends in Green Analytical Chemistry -- 7.1.2 Green Techniques for Sample Preparation -- 7.1.2.1 Reduction and Solvent Replacement -- Supercritical Fluid Extraction -- Membranes -- 7.1.2.2 Solvent Elimination -- Solid Phase Extraction (SPE) -- Matrix Solid-Phase Dispersion (MSPD) -- Sorptive Extraction Techniques -- Solid Phase Microextraction (SPME) -- Stir-Bar Sorptive Extraction -- 7.2 Conclusions -- References -- Chapter-8 -- Studies Regarding the Optimization of the Solvent Consumption in the Determination of Organochlor -- 8.1 Introduction -- 8.2 Materials and Methods -- 8.2.1 Materials -- 8.2.2 Methods -- 8.3 Results -- 8.4 Discussions -- 8.4.1 TRM1 -- 8.4.2 TRM2 -- 8.5 Conclusions -- References -- Chapter-9 -- Size Exclusion Chromatography a Useful Technique For Speciation Analysis of Polydimethylsiloxanes -- 9.1 Introduction to SEC -- 9.2 SEC Retention Mechanisms -- 9.2.1 Ideal Size Exclusion Mechanism -- 9.2.2 Non-Ideal Size Exclusion Mechanism -- 9.3 The Stationary Phase in SEC -- 9.4 The Mobile Phase in SEC -- 9.5 Analytical Problems -- 9.6 Methods for Column Calibration -- 9.7 Applications of SEC Biomedical and Pharmaceutical -- 9.7.1 SEC as a Useful Technique for Linear Polydimethylsiloxanes Speciation Analysis. , 9.8 Methodology for Linear Polydimethylsiloxanes Speciation Analysis -- 9.8.1 Mobile Phase Selection -- 9.8.2 Stationary Phase Selection -- 9.8.3 Column Conditions -- 9.8.4 Column Calibration -- 9.8.5 Separation of Polydimethylsiloxanes -- 9.9 Conclusions -- References -- Erratum -- Index.

Note: Intro -- Preface -- Contents -- Contributors -- Chapter 1: Nanophotocatalysts for Fuel Production -- 1.1 Introduction -- 1.2 Quantum Dot Semiconductors -- 1.3 Synthesis of Quantum Dots -- 1.4 Application of Quantum Dots for Fuel Production -- 1.5 Conclusion -- References -- Chapter 2: Highly Stable Metal Oxide-Based Heterostructured Photocatalysts for an Efficient Photocatalytic Hydrogen Production -- 2.1 Photocatalysis -- 2.1.1 Photocatalytic Mechanism -- 2.1.2 Band Edge Positions -- 2.2 Semiconducting Metal Oxides for Photocatalytic Water Splitting -- 2.2.1 Metal Oxide-Based Heterostructured Photocatalysts -- 2.2.1.1 Energy Structure of TiO2 -- 2.2.1.2 Lattice Structure of TiO2 -- 2.3 The Challenges in Photocatalytic H2 Production Using TiO2 Particulate Systems -- 2.4 Strategies for Improving TiO2 Photocatalytic Activity -- 2.4.1 Addition of Sacrificial Reagents -- 2.4.2 TiO2-Based Semiconductors Under UV Light Irradiation -- 2.4.3 Photocatalytic Performance of TiO2 Under Visible Irradiation -- 2.4.4 Functionalization of TiO2 with Carbon Nanomaterials -- 2.4.4.1 Carbon Nanotubes -- 2.4.4.2 Graphene Oxide/Reduced Graphene Oxide (RGO) -- 2.5 Future Scope/Conclusions -- References -- Chapter 3: Novelty in Designing of Photocatalysts for Water Splitting and CO2 Reduction -- 3.1 Introduction -- 3.2 CO2 Reduction -- 3.2.1 Principles of CO2 Reduction -- 3.2.2 By-Products of CO2 Reduction -- 3.2.3 Synthesis of Nanoparticles -- 3.2.3.1 Doping of Photocatalyst -- 3.2.4 Commercial Challenges of CO2 Reduction -- 3.3 Water Splitting -- 3.3.1 The Basic Principle of Water Splitting -- 3.3.2 Photocatalyst for Water Splitting -- 3.3.2.1 Oxide-Based Photocatalyst -- 3.3.2.2 Nitride-Based Photocatalyst -- 3.3.3 Commercial Challenges of Water Splitting -- 3.4 Conclusion and Way Forward -- References. , Chapter 4: Z-Scheme Photocatalysts for the Reduction of Carbon Dioxide: Recent Advances and Perspectives -- 4.1 Introduction -- 4.2 Basic Principles of the Z-Scheme Reduction of CO2 -- 4.3 Advances in Z-Scheme Photocatalytic Reduction of CO2 -- 4.3.1 Z-Scheme Systems with Aqueous Shuttle Redox Mediator -- 4.3.2 All-Solid-State Z-Scheme Systems -- 4.3.3 Semiconductor/Metal-Complex Hybrid Z-Scheme Systems -- 4.3.4 Light Harvesting of Photocatalysts Utilized for the Z-Scheme CO2 Reduction -- 4.3.5 Cocatalyst Strategies for Z-Scheme CO2 Reduction -- 4.4 Summary and Outlook -- References -- Chapter 5: Photocatalysts for Artificial Photosynthesis -- 5.1 Introduction -- 5.2 General Photosynthesis Mechanism -- 5.3 Covalently Linked Molecular Systems for Artificial Photosynthesis -- 5.3.1 Porphyrin-Based Donor-Acceptor Molecular Systems -- 5.3.2 Subphthalocyanine-Based Light-Harvesting Complexes -- 5.3.3 BODIPY-Based Light-Harvesting Systems -- 5.4 Supramolecular Artificial Photosynthetic Systems -- 5.4.1 Metal-Ligand Interactions of Porphyrins/Naphthalocyanines with Electron Acceptors -- 5.4.2 Supramolecular Photosynthetic Complexes Via Crown Ether-Ammonium Cation Interactions -- 5.5 Conclusion -- References -- Chapter 6: Polymeric Semiconductors as Efficient Photocatalysts for Water Purification and Solar Hydrogen Production -- 6.1 Introduction -- 6.2 Photocatalysis -- 6.2.1 Basic Principles of Photocatalytic Reaction -- 6.2.2 Photocatalytic Properties -- 6.2.3 Photocatalytic Mechanism -- 6.3 Photocatalytic Functional Materials: Synthesis, Properties and Applications -- 6.3.1 Graphitic Carbon Nitride (g-C3N4) -- 6.3.1.1 Synthesis of Polymeric g-C3N4 -- 6.3.1.2 Photocatalytic Mechanism of g-C3N4 -- 6.3.1.3 Photodegradation of Chemical Pollutants Using g-C3N4 -- 6.3.1.4 Graphene Oxide-Based Hybrid Photocatalysts. , 6.3.2 Metal-Organic Framework (MOF)-Based Photocatalysts -- 6.3.2.1 Principles -- 6.3.2.2 Photocatalytic Applications of MOFs -- 6.3.3 TiO2-Based Hybrid Photocatalysts -- 6.3.3.1 Principles -- 6.3.3.2 Different Forms of TiO2 and Its Physicochemical Properties -- 6.3.3.3 Structure of TiO2 -- 6.3.3.4 Photocatalytic Mechanism of TiO2 -- 6.3.3.5 Hybrid Photocatalysts Based on TiO2 and Organic Conjugated Polymers -- 6.3.3.5.1 Properties of Polythiophene -- 6.3.3.5.2 Properties of Polyaniline -- 6.3.3.5.3 Properties of Polypyrrole -- 6.3.3.5.4 Synthesis of TiO2-Based Hybrid Photocatalysts with Different Organic Conjugated Polymers -- 6.3.3.5.5 Characterization of TiO2/Conjugated Polymer-Based Hybrid Catalysts -- 6.3.3.5.6 Antibacterial Activity of Photocatalysts -- 6.3.3.6 Environmental Application of Different Photocatalysts -- 6.3.3.6.1 Water Purification -- 6.3.4 Graphene Oxide (GO)-Based Photocatalyst for Dye Degradation and H2 Evolution -- 6.3.4.1 Photodegradation of Chemical Pollutants -- 6.3.4.2 Hydrogen (H2) Evolution Reaction by g-C3N4-Based Functional Photocatalysts -- 6.4 Conclusion -- References -- Chapter 7: Advances and Innovations in Photocatalysis -- 7.1 Introduction -- 7.2 Photocatalysts for Hydrogen Production -- 7.2.1 Nature of Different Sacrificial Agents and Typical Mechanism of Photoreforming -- 7.2.1.1 Methanol as a Sacrificial Agent -- 7.2.1.2 Ethanol as a Sacrificial Agent -- 7.2.1.3 Glycerol as a Sacrificial Agent -- 7.2.1.4 Glucose as a Sacrificial Agent -- 7.2.2 Hydrogen Production from Photocatalytic Wastewater Treatment -- 7.3 Photocatalysts Developed for the Synthesis of Organic Compounds in Mild Conditions -- 7.3.1 The Starting Point -- 7.3.2 The Effect of Supporting Metal Oxides on Titania on Selectivity -- 7.3.3 The Effect of Titania Dopant -- 7.3.4 The Effect of Titania Surface Area. , 7.3.5 The Effect of Substituting Titania -- 7.3.6 The Effect of Reactor and Illumination -- 7.3.7 Cyclohexanol and Cyclohexanone by Gas-Phase Photocatalytic Oxidation? -- 7.4 Photocatalytic Membrane Reactors -- 7.5 Concluding Remarks -- References -- Chapter 8: Solar Light Active Nano-photocatalysts -- 8.1 Introduction -- 8.2 Mechanism of Semiconductor-Mediated Photocatalysis -- 8.2.1 Nano-TiO2 as Photocatalysts -- 8.2.2 Nano-ZnO as Photocatalysts -- 8.2.3 Graphitic Carbon Nitride as Photocatalysts -- 8.2.4 Titanates as Photocatalysts -- 8.2.5 Nano-metal Sulphides as Photocatalysts -- 8.3 Strategies for Making Solar/Visible Light Active Photocatalysts -- 8.3.1 Metal/Non-metal Doping -- 8.3.2 Addition of Photosensitive Materials -- 8.3.3 Construction of Heterojunctions/Composites -- 8.3.4 Construction of Nanohybrid Materials -- 8.3.5 Surface Modification -- 8.4 Conclusion -- References -- Chapter 9: High-Performance Photocatalysts for Organic Reactions -- 9.1 Introduction -- 9.2 Photocatalytic Oxidation of Alcohols -- 9.3 Selective Oxidation and Oxidative Coupling of Amines -- 9.4 Photocatalytic Cyanation -- 9.5 Photocatalytic Cycloaddition and C-C Bond Formation Reactions -- 9.6 Miscellaneous Reactions -- 9.7 Outlook -- 9.8 Conclusion -- References -- Index.

Note: Intro -- Preface -- Contents -- Chapter 1: Nanosponges for Carbon Dioxide Sequestration -- 1.1 Introduction -- 1.1.1 General Overview -- 1.1.2 Technologies to Capture CO2 -- 1.1.3 Functionalization -- 1.2 Characterization Techniques -- 1.2.1 N2 Adsorption/Desorption Isotherms at −196.15 °C -- 1.2.2 Transmission Electronic Microscopy -- 1.2.3 X Ray Diffraction -- 1.2.4 Elemental and Thermogravimetric Analysis -- 1.2.5 Nuclear Magnetic Resonance -- 1.2.6 Infrared Spectroscopy -- 1.2.7 Calorimetry -- 1.3 Amine-Functionalized Adsorbents -- 1.3.1 Amine Functionalized Zeolites -- 1.3.2 Amine Functionalized Activated Carbons -- 1.3.3 Amine Functionalized Metal Organic Frameworks -- 1.3.4 Amine-Functionalized Polymers -- 1.3.5 Amine-Functionalized Pore Expanded Silicas and Silica Nanosponges -- 1.3.6 Amine-Functionalized Modified Clays -- 1.4 Final Remarks -- References -- Chapter 2: Absorbents, Media, and Reagents for Carbon Dioxide Capture and Utilization -- 2.1 Introduction -- 2.2 Absorbents for Carbon Dioxide Capture and Subsequent Utilization -- 2.2.1 Amine Solution -- 2.2.2 Metal Hydroxide Solution -- 2.2.3 Ionic Liquid -- 2.2.4 Weak Base -- 2.2.5 Amino Acid Salt -- 2.2.6 Other Types of Absorbent -- 2.2.7 Overview -- 2.3 Conclusion -- References -- Chapter 3: Metal Oxides for Carbon Dioxide Capture -- 3.1 Introduction -- 3.2 Adsorption Technology for Carbon Dioxide Capture -- 3.3 High Temperature Solid Looping -- 3.3.1 Chemical Looping -- 3.4 Magnesium Oxide Based Adsorbents -- 3.4.1 Adsorption Mechanism -- 3.4.2 Performance Enhancement Strategies -- 3.5 Layered Double Oxides -- 3.5.1 Methodologies for Improving Capture Characteristics -- 3.6 Calcium Oxide Based Adsorbents -- 3.6.1 Strategies for Sustainable Reactivity -- 3.7 Metal Oxides for Oxygen Transfer in Chemical Looping Technology -- 3.8 Conclusions -- References. , Chapter 4: Hybrid Membranes for Carbon Capture -- 4.1 Introduction -- 4.2 Background -- 4.3 Mixed Matrix Membranes -- 4.3.1 Zeolites -- 4.3.2 Silica -- 4.3.3 Carbon Nano Tube -- 4.3.4 Carbon Molecular Sieve -- 4.3.5 Metal Organic Framework -- 4.3.6 Graphene -- 4.4 Preparation of Mixed Matrix Membranes -- 4.5 Summary and Outlook -- References -- Chapter 5: Ionic Liquids for Carbon Dioxide Capture -- 5.1 Introduction -- 5.2 Thermophysical Properties of Ionic Liquids -- 5.2.1 Viscosity -- 5.2.2 Thermal Stability -- 5.2.3 Biodegradability -- 5.3 Pure Ionic Liquids for CO2 Capture -- 5.3.1 Conventional Ionic Liquids -- 5.3.2 Task-Specific Ionic Liquids -- 5.3.3 Polymerized Ionic Liquids in CO2 Capture -- 5.4 CO2 Capture with Ionic Liquids Functionalized Solvents -- 5.4.1 Functionalizing the Anion of Ionic Liquid with Alkaline Group-NH2 -- 5.4.2 Attach the Anion of Ionic Liquid with Functional Group -- 5.5 CO2 Adsorption -- 5.5.1 Conventional Adsorbents -- 5.5.2 Solid Ionic Liquids -- 5.5.3 Supported Ionic Liquids onto a Solid Porous Material -- References -- Chapter 6: Carbon Sequestration in Alkaline Soils -- 6.1 Introduction -- 6.2 Management of Alkaline Soils -- 6.3 Carbon Stocks in Alkaline Soils -- 6.4 Factor Affecting Soil Carbon Degradation and Decomposition -- 6.5 Carbon Sequestration -- 6.6 Strategies for Carbon Sequestration in Alkaline Soils -- 6.6.1 Application of Amendments Containing Divalent Metals -- 6.6.2 Conservation Farming -- 6.6.3 Cover Crops -- 6.6.4 Manures and Composts -- 6.6.5 Crop Rotation/Selection -- 6.6.6 Biochar Intervention -- 6.6.7 Controlling Soil Erosion -- 6.6.8 Crop Residue Management -- 6.7 Conclusion and Future Research Opportunities -- References -- Chapter 7: Metal-Organic Frameworks for Carbon Dioxide Capture -- 7.1 Introduction -- 7.2 Literature Survey -- 7.2.1 Carbon Dioxide Capture and Storage. , 7.2.1.1 Carbon Dioxide Capture -- 7.2.1.2 Carbon Dioxide Transport and Storage -- 7.3 Current Carbon Dioxide Capture Technologies -- 7.3.1 Absorption- Amine Based Scrubbing -- 7.3.2 Absorption: Aqueous Ammonium Absorption -- 7.3.3 Surface Adsorption -- 7.4 Introduction to Metal-Organic Frameworks -- 7.4.1 Structure of Metal Organic Frameworks -- 7.4.2 MOF Properties and Applications -- 7.4.3 Zinc Based Metal Organic Frameworks (ZIFs) -- 7.5 Carbon Capture Using Metal Organic Frameworks -- 7.5.1 Adsorption of Carbon Dioxide on a Zirconium Based Metal Organic Framework (MOF) -- 7.5.1.1 Synthesis of Zirconium Based MOF (Zr-MOF) -- 7.5.1.2 Characterization of Prepared MOF -- 7.5.1.3 Results and Discussions -- 7.5.2 Adsorption of Carbon Dioxide on a Porous Carbon Material Derived from Zinc Based MOF -- 7.6 Conclusion -- References -- Chapter 8: Ionic Liquids for Carbon Dioxide Capture -- 8.1 Introduction -- 8.2 Ionic Liquids -- 8.3 Characteristics of Ionic Liquids -- 8.3.1 Melting Point -- 8.3.2 Critical Properties -- 8.3.3 Vapor Pressure -- 8.3.4 Thermal Stability -- 8.3.5 Density -- 8.3.6 Viscosity -- 8.3.7 Biodegradability -- 8.3.8 Solubility -- 8.3.9 Selectivity -- 8.3.10 Conductivity -- 8.4 Improving Ionic Liquids Performance -- 8.5 Previous Research -- 8.6 Important Factors for Choosing Suitable Ionic Liquid for Carbon Dioxide Capturing -- 8.7 Economic View -- 8.8 Challenge -- 8.9 Conclusion -- References -- Chapter 9: Methods for the Recovery of CO2 from Chemical Solvents -- 9.1 Introduction -- 9.2 Chemical and Physical Absorption -- 9.3 Characteristics of Chemical Solvents -- 9.3.1 Alkanolamines -- 9.3.2 Blend of Alkanolamines -- 9.3.3 Sterically Hindered Amines -- 9.3.4 Novel Amine-Based Solvents -- 9.3.5 Potassium Carbonate -- 9.3.6 Alkali Metal Hydroxide Solution -- 9.3.7 Ammonia Aqueous Solution -- 9.4 Methods of CO2 Recovery. , 9.4.1 Absorption/Desorption Process Through Packed Columns -- 9.4.2 Membrane Method -- 9.4.2.1 Polymeric Based Membranes -- 9.4.2.2 Ceramic and Metallic Membranes -- 9.4.2.3 Microporous Solid Membranes -- 9.4.3 Superiority of Membrane Method over Absorption/Desorption through Packed Columns Method -- 9.4.4 Membrane Flash Process -- 9.4.5 Eelectro Dialysis Membrane Process -- 9.4.6 Electrolysis Membrane Process -- 9.5 Conclusion -- References -- Chapter 10: Cryogenic CO2 Capture -- 10.1 Introduction -- 10.2 Pre-combustion Carbon Dioxide Capture -- 10.3 Oxy-Fuel Combustion Carbon Dioxide Capture -- 10.4 Post Combustion Carbon Dioxide Capture -- 10.5 Low Temperature Carbon Dioxide Capture Strategies -- 10.5.1 Cryogenic Distillation CO2 Capture -- 10.5.2 External Cooling Loop Cryogenic Carbon Dioxide Capture -- 10.5.3 Cryogenic Packed Bed -- 10.5.4 CO2 Cryogenic De-sublimation -- 10.5.5 Stirling Cooler Strategy -- 10.5.6 CryoCell System -- 10.5.7 Controlled Frosting Zone -- 10.6 Hybrid Methods for CO2 Capture -- 10.6.1 Cryogenic-Hydrate Technologies -- 10.6.2 Cryogenic -Membrane Technologies -- 10.6.3 Low Temperature Absorption Technologies -- 10.7 Advantages and Limitations of CO2 Capture Methods Based on Cryogenic Process -- 10.8 Conclusions -- References -- Index.

Note: Cover -- Half Title -- Title Page -- Copyright Page -- Table of Contents -- Preface -- Contributors -- Editors -- Chapter 1. Polythiophene-Based Battery Applications -- 1.1 Introduction -- 1.2 Synthesis -- 1.2.1 Electrochemical Polymerization -- 1.2.2 Chemical Synthesis -- 1.3 Battery Applications of PTs -- 1.3.1 PTs as Cathodic Materials -- 1.3.1.1 PTs as Active Materials -- 1.3.1.2 PTs as Binder -- 1.3.1.3 PTs as Conduction-Promoting Agents -- 1.3.2 PTs as Air Cathode -- 1.3.2.1 Li-Air Batteries -- 1.3.2.2 Aluminum-Air Battery -- 1.3.2.3 Zinc-Air Battery -- 1.3.3 PTs as Anodic Materials -- 1.3.3.1 PTs as Active Materials for Anode -- 1.3.3.2 PTs as Binders -- 1.3.3.3 PTs as Conduction Promoting Agents (CPAs) -- 1.3.4 PTs as Battery Separators -- 1.3.4.1 Li-Ion Batteries -- 1.3.4.2 Li-S Batteries -- 1.3.4.3 Li-O2 Batteries -- 1.3.5 PTs as Electrolytes -- 1.3.6 PTs as Coin-cell Cases -- 1.3.7 PTs as Li-O2 Catalyst -- 1.4 Conclusion -- References -- Chapter 2. Synthetic Strategies and Significant Issues for Pristine Conducting Polymers -- 2.1 Introduction -- 2.2 Conduction Mechanism -- 2.3 Synthesis of Conducting Polymers -- 2.3.1 Synthesis through Polymerization -- 2.3.1.1 Chain-Growth Polymerization -- 2.3.1.2 Step-Growth Polymerization -- 2.3.2 Synthesis by Doping with Compatible Dopants -- 2.3.2.1 Types of Doping Agents -- 2.3.2.2 Doping Techniques -- 2.3.2.3 Mechanism of Doping -- 2.3.2.4 Influence of Doping on Conductivity -- 2.3.3 Electrochemical Polymerization -- 2.3.4 Photochemical Synthesis -- 2.4 Various Issues for Synthesis -- 2.4.1 Vapor-Phase Polymerization -- 2.4.2 Hybrid Conducting Polymers -- 2.4.3 Nanostructure Conducting Polymers -- 2.4.4 Narrow Bandgap Conducting Polymers -- 2.4.5 Synthesis in Supercritical CO2 -- 2.4.6 Biodegradability and Biocompatibility of Conducting Polymers -- 2.5 Applications. , 2.6 Future Scope for Applications -- 2.7 Conclusions -- Abbreviations -- References -- Chapter 3. Conducting Polymer Derived Materials for Batteries -- 3.1 Introduction -- 3.2 Theory -- 3.3 Discussion on Conducting Polymer-Derived Materials -- 3.3.1 PEDOT Derivatives -- 3.3.1.1 Structural Properties -- 3.3.1.2 Electrochemical Studies of PEDOT and Its Derivatives -- 3.3.1.3 Magnetic Properties -- 3.3.2 PPy for the Energy-Storage Devices -- 3.3.2.1 Structural Property of PPy -- 3.3.2.2 Electrochemical Properties of Polypyrrol -- 3.3.2.3 Magnetic Properties -- 3.3.3 PANI for Battery Application -- 3.3.3.1 Structural Properties -- 3.3.3.2 Electrochemical Properties of PANI for Battery Electrode -- 3.3.3.3 Magnetic Properties of PANI -- 3.4 Summary and Conclusions -- References -- Chapter 4. An Overview on Conducting Polymer-Based Materials for Battery Application -- 4.1 Introduction -- 4.2 Principle of Conducting Polymer Battery -- 4.3 Assortment of Conducting Polymer Electrodes for Battery Application -- 4.4 Mechanism of Conducting Polymers in Rechargeable Batteries -- 4.5 Organic Conducting Polymer for Lithium-ion Battery -- 4.5.1 Types of Organic Conducting Polymers -- 4.6 Synthesis of Conducting Polymer -- 4.6.1 Hard-template Method -- 4.6.2 Soft-template Method -- 4.6.3 Template-free Technique -- 4.6.4 Self-Assembly or Interfacial -- 4.6.5 Electrospinning -- 4.7 Characterization -- 4.7.1 Surface Characterization by AFM and AFMIR -- 4.7.2 Transmission Electron Microscopy -- 4.7.3 Electrochemical Characterization -- 4.8 Applications of Various Conducting Polymers in Battery -- 4.8.1 Polyacetylene Battery -- 4.8.2 Polyaniline Batteries -- 4.8.3 Poly (p-phenylene) Batteries -- 4.8.4 Heterocyclic Polymer Batteries -- 4.9 Summary and Outlook -- References -- Chapter 5. Polymer-Based Binary Nanocomposites -- 5.1 Introduction -- 5.2 Binary Composites. , 5.3 Nanostructured CPs -- 5.4 Strategies to Improve Performance -- 5.4.1 Low-dimensional Capacitors -- 5.4.2 Hybrid Capacitors -- 5.4.2.1 Hybrid Electrode Material -- 5.5 CP/Carbon-based Binary Composite -- 5.6 CP/Metal Oxides Binary Composites -- 5.7 CP/Metal Sulfides Binary Complexes -- 5.8 Other Cp-supported Binary Complexes -- 5.9 Conclusion -- References -- Chapter 6. Polyaniline-Based Supercapacitor Applications -- 6.1 Introduction -- 6.2 Polyaniline (PANI) and Its Application Potential -- 6.3 Supercapacitors -- 6.3.1 PANI in Supercapacitors -- 6.3.2 PANI and Carbon Composites -- 6.3.3 PANI/Porous and Carbon Composites -- 6.3.4 PANI/Graphene Composites -- 6.3.5 PANI/CNTs Composites -- 6.3.6 Polyaniline Activation/Carbonization -- 6.3.7 Composites of Polyaniline with Various Conductive Polymer Blends -- 6.3.8 Composites of Polyaniline with Transition Metal Oxides -- 6.3.9 Composites of Polyaniline Core-Shells with Metal Oxides -- 6.3.10 PANI-modified Cathode Materials -- 6.3.11 PANI-modified Anode Materials -- 6.4 Redox-active Electrolytes for PANI Supercapacitors -- 6.5 Examples of Various Polyaniline-based Supercapacitor -- 6.5.1 Composites of Polyaniline Doped with CoCl2 as Materials for Electrodes -- 6.5.2 Composites of Polyaniline Nanofibers with Graphene as materials for electrodes -- 6.5.3 Composites of Polyaniline (PANI) with Graphene Oxide as Electrode Materials -- 6.5.4 Hybrid Films of Manganese Dioxide and Polyaniline as Electrode Materials -- 6.5.5 Composites of Activated Carbon/Polyaniline with Tungsten Trioxide as Electrode Materials -- 6.5.6 PANI- and MOF-based Flexible Solid-state Supercapacitors -- 6.5.7 Polyaniline-based Nickel Electrodes for Electrochemical Supercapacitors -- 6.5.8 Hydrogel of Ultrathin Pure Polyaniline Nanofibers in Supercapacitor Application -- Conclusion -- Acknowledgements -- References. , Chapter 7. Conductive Polymer-derived Materials for Supercapacitor -- 7.1 Introduction -- 7.2 Types of Supercapacitor -- 7.3 Parameters of Supercapacitors -- 7.4 Conducting Polymers (CPs) as Electrode Materials -- 7.4.1 Class of Conducting Polymer as Supercapacitor Electrode -- 7.5 Polyaniline (PANI)-based Electrode -- 7.6 Polypyrrole (PPy)-based Electrode -- 7.7 Polythiophene (PTh)-based Electrode -- 7.8 Conclusions -- Acknowledgement -- References -- Chapter 8. Conducting Polymer-Metal Based Binary Composites for Battery Applications -- 8.1 Conducting polymer (CPs) -- 8.2 Conducting polymers conductivity -- 8.3 Conducting polymer composites -- 8.3.1 Metal center nanoparticles -- 8.3.2 Metal nanoparticles -- 8.4 Conducting Polymer Based Binary Composites -- 8.4.1 Metal Matrix Composites (MMC) -- 8.4.2 Poly (Thiophene) composite -- 8.4.3 Poly (Para-Phenylene Vinylene) composite -- 8.4.4 Poly (Carbazole) composite -- 8.4.5 Vanadium oxide based conducting composite -- 8.4.6 PANI-V2O5 composite -- 8.4.7 Poly(N-sulfo propyl aniline)-V2O5 composite -- 8.5 Conducting polymer composite battery applications -- 8.5.1 Conducting polymer composite for Lithium-ion (Li+) based battery -- 8.5.2 Conducting polymer composites for Sodium-ion (Na+) based Battery -- 8.5.3 Conducting Polymer composite for Mg-Ion (Mg+2) Based Battery -- 8.6 Conducting polymer based composites for electrode materials -- References -- Chapter 9. Novel Conducting Polymer-Based Battery Application -- 9.1 Conducting Polymers (CPs) -- 9.1.1 Poly(Acetylene) -- 9.1.2 Poly(Thiophene) -- 9.1.3 Poly(Aniline) -- 9.1.4 Poly(Pyrrole) -- 9.1.5 Poly(Paraphenylene) and Poly(Phenylene) -- 9.2 Battery Applications of Conducting Polymers -- 9.2.1 Lithium Sulfide batteries -- 9.2.2 Binder for Lithium sulfide battery cathode -- 9.2.3 Sulfur encapsulation for electrode materials. , 9.2.4 Sulfur Encapsulation through Conductive Polymers -- 9.2.5 Conducting polymer anodes for Lithium sulfide battery -- 9.2.6 Conducting polymer as materials interlayer -- 9.3 Li+-ion-based Battery Applications of Conducting Polymers -- 9.4 Na+- ion-based Battery Applications of Conducting Polymers -- 9.5 Mg+2-ion-based Battery Applications of Conducting Polymers -- References -- Chapter 10. Conducting Polymer-Carbon-Based Binary Composites for Battery Applications -- Abbreviations -- 10.1 Introduction -- 10.2 Batteries -- 10.2.1 Types of Batteries -- 10.2.2 Electrode Materials -- 10.3 Conducting Polymer-Carbon-Based Binary Composite in Battery Applications -- 10.3.1 Polyaniline PANI-Carbon-Based Composite -- 10.3.2 Polypyrrole (PPy)-Carbon-Based Composite -- 10.3.3 Poly(3,4-ethylenedioxythiophene) (PEDOT)-Carbon-Based Composite -- 10.3.4 Others Conducting Polymer-Carbon-Based Composite -- 10.4 Conclusions -- Acknowledgements -- References -- Chapter 11. Polyethylenedioxythiophene-Based Battery Applications -- 11.1 Chemistry of PEDOT -- 11.1.1 PEDOT Synthesis and Morphology -- 11.1.1.1 Synthetic Techniques to Achieve Desired Morphologies -- 11.1.2 PEDOT-Based Nanocomposites -- 11.2 PEDOT-Based Polymers in Lithium-Sulfur Batteries -- 11.3 Lithium-Air Battery Based on PEDOT or PEDOT:PSS -- 11.3.1 PEDOT-Based Nanocomposites for Li-O2 Batteries -- 11.3.2 PEDOT:PSS-Based Li-O2 Battery Cathodes -- 11.4 Lithium and Alkali Ion Polythiophene Batteries -- 11.4.1 Cathodes -- 11.4.1.1 Cathode Binders and Composites -- 11.4.2 Anodes -- 11.4.2.1 Anode Binders and Composites -- 11.4.3 All-Polythiophene and Metal-Free Batteries -- References -- Chapter 12. Polythiophene-Based Supercapacitor Applications -- 12.1 Introduction -- 12.2 Properties of Polythiophene (PTh) -- 12.3 Synthesis of Polythiophene -- 12.4 Charge Storage in Polythiophene Electrochemical Capacitors. , 12.5 Polythiophene Electrode Fabrication.

Note: Intro -- Foreword -- Contents -- About the Editors -- Chapter 1: Analytical Methods for the Determination of Heavy Metals in Water -- 1.1 Introduction -- 1.2 Total Concentration and Speciation Analysis -- 1.3 Health and Legislation -- 1.4 Sample Preparation for Elemental Analysis of Heavy Metals -- 1.4.1 Solid-Phase Extraction -- 1.4.1.1 Classic Solid-Phase Extraction -- 1.4.1.1.1 Modern Sorbents for Classic Solid-Phase Extraction -- 1.4.1.1.2 Micro Solid-Phase Extraction -- 1.4.1.2 Dispersive Solid-Phase Extraction -- 1.4.1.2.1 Dispersion Techniques -- 1.4.1.2.2 Modern Sorbents for Dispersive Solid-Phase Extraction and Dispersive Micro-Solid Phase Extraction -- Nanostructured Materials -- Hybrid Materials -- 1.4.1.3 Magnetic Solid-Phase Extraction -- 1.4.1.3.1 Advanced Magnetic Sorbents -- 1.4.2 Liquid-Liquid Extraction -- 1.4.2.1 Modern Solvents Used in Liquid-Liquid Extraction -- 1.4.2.1.1 Non-ionic or Zwitterionic Surfactants -- 1.4.2.1.2 Ionic Liquids -- 1.4.2.1.3 Deep Eutectic Solvents -- 1.4.2.2 Novel Liquid-Liquid Microextraction Techniques -- 1.4.2.2.1 Dispersive Liquid-Liquid Microextraction Techniques -- 1.4.2.2.2 In-Situ Phase Separation Techniques -- 1.4.2.2.3 Cloud Point Extraction -- 1.4.2.2.4 Non-dispersive Microextraction Techniques -- 1.4.2.3 Liquid-Liquid Extraction in Flow Analysis -- 1.5 Analytical Techniques for Heavy Metal Detection -- 1.5.1 Spectroscopic Techniques -- 1.5.1.1 Atomic Absorption Spectroscopy -- 1.5.1.2 Atomic Fluorescence Spectrometry -- 1.5.1.3 Atomic Emission Spectrometry -- 1.5.1.4 Inductively Coupled Plasma-Mass Spectrometry -- 1.5.1.4.1 Single Particle Inductively Coupled Plasma-Mass Spectrometry -- 1.5.1.5 Laser-Induced Breakdown Spectroscopy -- 1.5.1.6 X-Ray Fluorescence -- 1.5.1.7 UV-Vis Spectrophotometry -- 1.5.2 Electrochemical Techniques -- 1.5.2.1 Potentiostatic Techniques. , 1.5.2.1.1 Amperometry -- 1.5.2.1.2 Chronocoulometry -- 1.5.2.1.3 Voltammetric Techniques -- 1.5.2.2 Galvanostatic Stripping Chronopotentiometry -- 1.5.2.3 Electrochemiluminescence -- 1.5.3 Other Methods -- 1.5.3.1 Ion Chromatography -- 1.5.3.2 Surface-Enhanced Raman Spectroscopy -- 1.5.3.3 Bio Methods -- 1.6 Conclusions and Future Perspectives -- References -- Chapter 2: Olive-Oil Waste for the Removal of Heavy Metals from Wastewater -- 2.1 Introduction -- 2.2 Olive Tree Pruning as Biosorbent of Heavy Metals from Aqueous Solutions -- 2.2.1 Characterization -- 2.2.2 Biosorption Tests -- 2.3 Olive Stone as Biosorbent of Heavy Metals from Aqueous Solutions -- 2.3.1 Characterization -- 2.3.2 Biosorption Tests -- 2.4 Olive Pomace and Olive-Cake as Biosorbents of Heavy Metals from Aqueous Solutions -- 2.4.1 Characterization -- 2.4.2 Biosorption Tests -- 2.5 Other Valorization Opportunities for Olive-Oil Waste -- 2.6 Conclusions -- References -- Chapter 3: Metal Oxide Composites for Heavy Metal Ions Removal -- 3.1 Introduction -- 3.2 Issues in Environmental Remediation -- 3.3 Different Types of Magnetic Sorbents -- 3.3.1 Iron Oxide Modified Nanoparticle -- 3.3.2 Zeolite -- 3.3.3 Silica -- 3.3.4 Polymer Functionalization -- 3.3.5 Chitosan and Alginate -- 3.3.6 Activated Carbon -- 3.3.7 Carbon Nanotubes (CNTs) and Graphene -- 3.3.8 Agricultural Wastes -- 3.4 Case Studies -- 3.4.1 Characterization -- 3.4.2 Factors Affecting Sorption Processes -- 3.4.3 Agro-Based Magnetic Biosorbents Recovery and Reusability -- 3.5 Conclusion -- References -- Chapter 4: Two-Dimensional Materials for Heavy Metal Removal -- 4.1 Introduction -- 4.2 Heavy Metal Ions Removal Mechanism -- 4.2.1 Surface Complexation -- 4.2.2 Van der Waals Interaction -- 4.2.3 Ion Exchange -- 4.3 Different Types of Two-Dimensional Material for Heavy Metal Removal. , 4.3.1 Graphene-Based Two-Dimensional Materials -- 4.3.1.1 Structure -- 4.3.1.2 Graphene-Based Materials for Heavy Metal Removal -- 4.3.2 Dichalcogenides -- 4.3.2.1 Structure -- 4.3.2.2 Molybdenum Disulfide for Heavy Metal Removal -- 4.3.3 MXenes -- 4.3.3.1 Structure -- 4.3.3.2 MXenes for Heavy Metal Removal -- 4.3.4 Clay Minerals -- 4.3.4.1 Structure -- 4.3.4.2 Clay Mineral for Heavy Metal Removal -- 4.3.5 Layered Double Hydroxides -- 4.3.5.1 Structure -- 4.3.5.2 Layered Double Hydroxides for Heavy Metal Removal -- 4.3.6 Layered Zeolites -- 4.3.6.1 Structure -- 4.3.6.2 Layered Zeolites for Heavy Metal Removal -- 4.3.7 Other Two-Dimensional Materials -- 4.4 Heavy Metal Removal Other than Adsorption -- 4.5 Conclusions and Perspectives -- Appendix: List of Two-Dimensional Materials that Mentioned in this Chapter for Heavy Metal Removal and their Removal Capacities -- References -- Chapter 5: Membranes for Heavy Metals Removal -- 5.1 Introduction -- 5.2 Electrodialysis -- 5.2.1 Electrodialysis Applied to Metal Removal -- 5.2.2 Principle -- 5.2.3 Evaluation and Control Parameters -- 5.2.4 Use in Electroplating Industry -- 5.2.4.1 Zinc -- 5.2.4.2 Chromium -- 5.2.4.3 Copper -- 5.2.4.4 Nickel -- 5.2.5 Use in Mining and Mineral Processing Industry -- 5.2.6 Final Considerations -- References -- Chapter 6: Metal Oxides for Removal of Heavy Metal Ions -- 6.1 Introduction -- 6.2 Adsorption Methods -- 6.3 Metal Oxides for the Removal of Heavy Metal Ions from Water -- 6.3.1 Titanium Dioxide -- 6.3.2 Manganese Dioxide -- 6.3.3 Iron Oxide -- 6.3.4 Aluminum Oxide -- 6.3.5 Binary Metal Oxides -- 6.4 Conclusion -- References -- Chapter 7: Organic-Inorganic Ion Exchange Materials for Heavy Metal Removal from Water -- 7.1 Introduction -- 7.2 Ion Exchange Process -- 7.3 Ion Exchange Materials -- 7.3.1 Inorganic Ion Exchangers -- 7.3.2 Organic Ion Exchangers. , 7.4 Heavy Metal Removal with Ion Exchange Materials -- 7.4.1 Lead (II) Removal from Wastewater with Organic-Inorganic Ion Exchangers -- 7.4.2 Mercury (II) Removal from Waste Water with Organic-Inorganic Ion Exchangers -- 7.4.3 Cadmium (II) Removal from Wastewater with Organic-Inorganic Ion Exchangers -- 7.4.4 Nickel (II) Removal from Wastewater with Organic-Inorganic Ion Exchangers -- 7.4.5 Chromium (III, VI) Removal from Wastewater with Organic-Inorganic Ion Exchangers -- 7.4.6 Copper (II) Removal from Wastewater with Organic-Inorganic Ion Exchangers -- 7.4.7 Zinc (II) Removal from Wastewater with Organic-Inorganic Ion Exchangers -- 7.5 Conclusion -- References -- Chapter 8: Low-Cost Technology for Heavy Metal Cleaning from Water -- 8.1 Introduction -- 8.2 Sources and Impact -- 8.3 Different Routes of Contamination -- 8.4 Conventional Water Treatment Methods -- 8.4.1 Preliminary Treatment -- 8.4.2 Secondary Water Treatment -- 8.4.3 Tertiary Water Treatment -- 8.4.4 Membrane Filtration -- 8.5 Advanced Technology for Heavy Metal Ion Removal -- 8.5.1 Nano-Adsorption -- 8.5.2 Molecularly-Imprinted Polymers -- 8.5.3 Layered Double Hydroxides (LDH) and Covalent-Organic Framework (COF) -- 8.5.4 Emerging Membrane Technologies -- 8.6 Low-Cost and Biotechnological Approaches -- 8.6.1 Biosorption -- 8.6.2 Microbial Remediation -- 8.6.3 Biotechnological Strategies -- 8.7 Conclusion -- References -- Chapter 9: Use of Nanomaterials for Heavy Metal Remediation -- 9.1 General Introduction -- 9.2 Heavy Metals in the Environment -- 9.2.1 Characteristics of Selected Heavy Metals -- 9.3 Wastewater Treatment -- 9.4 Nanomaterials -- 9.4.1 Clay Minerals -- 9.4.2 Layered Double Hydroxide and Their Mixed-Oxides Counterparts -- 9.4.3 Zeolites -- 9.4.4 Two-dimensional Early Transition Metal Carbides and Carbonitrides -- 9.4.5 Metal Based Nanoparticles. , 9.4.5.1 Zero-valent Metals -- 9.4.5.2 Metal Oxides -- 9.4.6 Carbon-based Materials -- 9.4.6.1 Carbon Nanotubes -- 9.4.6.2 Fullerenes -- 9.4.6.3 Graphene -- 9.4.6.4 Graphene Oxide -- 9.4.6.5 Reduced Graphene Oxide -- 9.4.6.6 Graphitic Carbon Nitride -- 9.4.7 Metal Organic Frameworks -- 9.5 Disadvantages of Using Nanomaterials -- 9.6 Conclusions -- References -- Chapter 10: Ecoengineered Approaches for the Remediation of Polluted River Ecosystems -- 10.1 Introduction -- 10.2 Occurrence of Pollutants, Emerging Contaminants and Their Riverine Fates -- 10.3 Hazardous Effects of Water Contaminants on Aquatic and Terrestrial Biota -- 10.4 Historic Concepts of River Bioremediation -- 10.5 Physico-chemical River Remediation Methods -- 10.6 Eco-engineered River Water Remediation Technologies -- 10.6.1 Plant Based River Remediation Systems -- 10.6.1.1 Constructed Wetlands -- 10.6.1.2 Ecological Floating Wetlands, Beds and Islands -- 10.6.1.3 Eco-tanks -- 10.6.1.4 Bio-racks -- 10.6.2 Microorganisms Based River Remediation Systems -- 10.6.2.1 Biofilm Based Eco-engineered Treatment Systems -- 10.6.2.1.1 Bio-filters in River Bioremediation -- 10.6.2.2 Periphyton Based Technologies -- 10.7 In Situ Emerging Integrated Systems for the River Bioremediation -- 10.8 Concluding Remarks -- References -- Chapter 11: Ballast Water Definition, Components, Aquatic Invasive Species, Control and Management and Treatment Technologies -- 11.1 Introduction -- 11.2 Component of Ballast Water -- 11.3 Aquatic Invasive Species -- 11.4 The International Convention for the Control and Management of Ships Ballast Water and Sediments -- 11.5 IMO Standards for Ballast Water Quality -- 11.6 Management Options of Ballast Water -- 11.7 Ballast Water Treatment Technologies -- 11.7.1 Mechanical Treatment -- 11.7.2 Physical Treatment -- 11.7.2.1 Ultrasound and Cavitation. , 11.7.3 Chemical Treatment.

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.