Note: Cover -- Half Title -- Title Page -- Copyright Page -- Contents -- Preface -- Editors -- Contributors -- Chapter 1: Graphene from Sugar and Sugarcane Extract: Synthesis, Characterization, and Applications -- Chapter 2: Graphene from Honey -- Chapter 3: Graphene from Animal Waste -- Chapter 4: Graphene from Essential Oils -- Chapter 5: Synthesis of Graphene from Biowastes -- Chapter 6: Graphene from Rice Husk -- Chapter 7: Synthesis of Graphene from Vegetable Waste -- Chapter 8: Graphene Oxide from Natural Products and Its Applications in the Agriculture and Food Industry -- Chapter 9: Graphene from Sugarcane Bagasse: Synthesis, Characterization, and Applications -- Chapter 10: Graphene Synthesis, Characterization and Applications -- Chapter 11: Graphene from Leaf Wastes -- Chapter 12: Biosynthesis of Reduced Graphene Oxide and Its Functionality as an Antibacterial Template -- Chapter 13: Graphene and Its Composite for Supercapacitor Applications -- Index.

Note: Cover -- Title -- Copyright -- End User License Agreement -- Contents -- Preface -- List of Contributors -- Microbial Remediation of Heavy Metals -- Removal of Heavy Metals using Microbial Bioremediation -- Deepesh Tiwari1, Athar Hussain2,*, Sunil Kumar Tiwari3, Salman Ahmed4, Mohd. Wajahat Sultan5 and Mohd. Imran Ahamed6 -- INTRODUCTION -- HEAVY METALS: SOURCES AND EFFECTS -- HEAVY METALS OCCURRENCES -- HEAVY METAL REMOVAL STRATEGIES -- Physical Methods -- Chemical Methods -- Biological Methods -- Phytoremediation -- Bioremediation -- Mechanism of Bioremediation -- Bioremediation by Biosorption -- Bioremediation by Bioaccumulation -- Comparison of Biosorption and Bioaccumulation Process -- Biotechnological Intervention in Bioremediation Processes by the Microbial Approach -- The Ability of Microorganisms to Bioremediate Heavy Metals -- Bacteria Remediation Capacity of Heavy Metal -- Fungi Remediation Capacity of Heavy Metal -- Remediation Capacity of Heavy Metal by Algae -- Heavy Metal Removal Using Biofilms -- Plant Approach -- Advantages of Bioremediation -- Disadvantages of Bioremediation -- CONCLUSION -- CONSENT FOR PUBLICATION -- CONFLICT OF INTEREST -- ACKNOWLEDGEMENTS -- REFERENCES -- Bioremediation of Heavy Metal in Paper Mill Effluent -- Priti Gupta1,* -- INTRODUCTION -- PAPER & -- PULP INDUSTRY: GLOBAL OUTLOOK ON UTILITY AND GROWTH -- PAPER & -- PULP INDUSTRY: GLOBAL OUTLOOK ON HAZARDS -- PAPER MAKING PROCESSES AND WASTEWATER GENERATION -- Debarking -- Pulping -- Mechanical Pulping -- Chemical Pulping -- Bleaching -- Washing -- Stock Preparation and Paper Making Process -- HEAVY METALS AT GLANCE -- Adverse Effect of Heavy Metal Contamination -- Soil -- Microbial Population -- Plants -- Animals -- Humans -- Remediation Technologies for the Treatment of Heavy Metal Contaminated Wastewater Effluent. , BIOREMEDIATION: AN INNOVATIVE AND USEFUL APPROACH -- Industrial by-Products -- Agricultural Wastes -- Phytoremediation Methods and its Types -- Microbial Biosorbents -- MICROBIAL BIOREMEDIATION METHODS -- Biosorption -- How Does Biosorption Works? -- Important Factors Governing Biosorption Mechanism -- Types of Biosorption -- Examples of Efficient Biosorbents -- Advantages -- Biotransformation -- Bioaccumulation -- Bioleaching -- FACTORS AFFECTING MICROBIAL REMEDIATION OF HEAVY METALS -- CHALLENGES -- CONCLUSION AND FUTURE ASPECTS -- CONSENT FOR PUBLICATION -- CONFLICT OF INTEREST -- ACKNOWLEDGEMENTS -- REFERENCES -- Bioremediation of Pesticides -- Praveen Kumar Yadav1,2,*, Kamlesh Kumar Nigam3, Shishir Kumar Singh2,4, Ankit Kumar5 and S. Swarupa Tripathy1 -- INTRODUCTION -- Pesticides -- Bioremediation of Pesticides -- Type of Bioremediation -- In-situ Bioremediation -- Ex-situ Bioremediation -- Aerobic Bioremediation -- Anaerobic Bioremediation -- Mycodegradation of Pesticides -- Mycodegradation of Pesticides -- Bacterial Degradation of Pesticides -- Mechanisms Involved in Bioremediation -- Genetic Modification in Bioremediation Tools -- CONCLUSION -- CONSENT FOR PUBLICATION -- CONFLICT OF INTEREST -- ACKNOWLEDGEMENTS -- REFERENCES -- Biosurfactants for Biodégradation -- Telli Alia1,* -- INTRODUCTION -- BIOSURFACTANTS -- Definition and Importance -- Surface Activity -- Critical Micelle Concentration (CMC) -- Hydrophile-lipophile Balance -- Emulsion Stability -- Classification, Properties and Applications of Biosurfactants -- APPLICATION OF BIOSUFACTANT IN BIODEGRADATION -- Biodegradation of Crude Oil and Petroleum Wastes -- Removal and Detoxification of Heavy Metals -- Biodegradation of Pesticides -- Biodegradation of Organic Dyes -- CONCLUSION -- CONSENT FOR PUBLICATION -- CONFLICT OF INTEREST -- ACKNOWLEDGEMENT -- REFERENCES. , Potential Application of Biological Treatment Methods in Textile Dyes Removal -- Rustiana Yuliasni1, Bekti Marlena1, Nanik Indah Setianingsih1, Abudukeremu Kadier2,3,*, Setyo Budi Kurniawan4, Dongsheng Song2,5 and Peng-Cheng Ma2,3 -- INTRODUCTION -- HISTORY AND CLASSIFICATION OF DYES -- History of Textile Dyes -- Classification of Dyes Based on Industrial Application -- Direct Dyes -- Disperse Dyes -- Vat Dyes -- Basic Dyes -- Acid Dyes -- Sulphur Dyes -- Azo Dyes -- Reactive Dyes -- Dyes Classification Based on Chromophores -- ENVIRONMENTAL CONCERN RELATED TO DYES -- DYES REMOVAL TECHNIQUES -- BIODEGRADATION MECHANISMS OF DYES -- Biosorption -- Bioaccumulation -- Biodegradation -- FUTURE PROSPECTS FOR APPLICATION -- CONCLUSION -- CONSENT FOR PUBLICATION -- CONFLICT OF INTEREST -- ACKNOWLEDGEMENTS -- REFERENCES -- Fungal Bioremediation of Pollutants -- Evans C. Egwim1,*, Oluwafemi A. Oyewole2 and Japhet G. Yakubu2 -- INTRODUCTION -- Pollutants and Their Classification -- Petroleum Hydrocarbons -- Heavy Metals -- Chemical Pollutants -- Synthetic Pesticides -- Industrial Dyes -- Pharmaceutical Products -- Effects of Pollutants in the Soil -- Effects of Pollutants in the Aquatic Environment -- Effects of Pollutants in the Air -- Bioremediation -- Bioremediation Techniques -- Biosparging -- Bioventing -- Bioaugmentation -- Biostimulation -- Ex situ -- Solid Phase -- Land Farming -- Composting -- Biopiles -- Slurry Phase -- Fungi -- Mycoremediation -- White Rot Fungi -- Enzyme System of WRF -- Lignin Peroxidase -- Manganese Peroxidase -- Versatile Peroxidase -- Laccase -- Cytochrome P450s Monooxygenase -- Mycoremediation of Pollutants -- Mycoremediation of Petroleum Hydrocarbons -- Mycoremediation of Dyes -- Mycoremediation of Pesticides -- Mycoremediation of Pharmaceutical Products -- Mycoremediation of Heavy Metal -- Advantages of Mycoremediation. , Limitations of Mycoremediation -- Nutrients -- Bioavailability of Pollutants -- Temperature -- Effects of pH -- Relative Humidity -- Toxicity of Pollutants -- Oxygen -- Moisture Content -- Presence of Contaminants -- CONCLUSION AND FUTURE PERSPECTIVE -- CONSENT FOR PUBLICATION -- CONFLICT OF INTEREST -- ACKNOWLEDGEMENT -- REFERENCES -- Antifouling Nano Filtration Membrane -- Sonalee Das1,* and Lakshmi Unnikrishnan1 -- INTRODUCTION -- MEMBRANE FOULING -- Classification of Membrane Fouling -- Mechanism of Membrane Fouling -- Factors Affecting Membrane Fouling -- NANOFILTRATION MEMBRANES -- Mechanism of Action -- Characterization of NF Membranes -- Industrial Applications -- Challenges in NF Membranes -- Membrane Fouling -- Separation Between the Solutes -- Post-treatment of Concentrates -- Chemical Resistance -- Insufficient Rejection in Water Treatment -- Need for Modelling & -- Simulation Tools -- ANTIFOULING NANOFILTRATION (AF-NF) MEMBRANES -- Recent Progress in the Fabrication of Anti-Fouling Nanofiltration (NF) Membranes -- CONCLUSION -- CONSENT FOR PUBLICATION -- CONFLICT OF INTEREST -- ACKNOWLEDGEMENT -- Microbes and their Genes involved in Bioremediation of Petroleum Hydrocarbon -- Bhaskarjyoti Gogoi1, Indukalpa Das1, Shamima Begum1, Gargi Dutta1, Rupesh Kumar1 and Debajit Borah1,* -- INTRODUCTION -- TYPES OF BIOREMEDIATION STRATEGIES -- PHYSICAL METHOD FOR BIOREMEDIATION OF PETROLEUM HYDROCARBON -- CHEMICAL METHOD FOR BIOREMEDIATION OF PETROLEUM HYDROCARBON -- BIOLOGICAL METHODS -- EX-SITU BIOREMEDIATION -- In Situ Bioremediation -- Microbial Bioremediation Method -- ROLE OF BIOSURFACTANTS IN PETROLEUM HYDROCARBON DEGRADATION -- ROLE OF MICROBIAL ENZYMES AND RESPONSIBLE GENES IN HYDROCARBON DEGRADATION -- FACTORS AFFECTING BIOREMEDIATION OF PETROLEUM HYDROCARBONS -- CONCLUSION -- CONSENT FOR PUBLICATION -- CONFLICT OF INTEREST. , ACKNOWLEDGEMENT -- REFERENCES -- Application and Major Challenges of Microbial Bioremediation of Oil Spill in Various Environments -- Rustiana Yuliasni1, Setyo Budi Kurniawan2, Abudukeremu Kadier3,4,*, Siti Rozaimah Sheikh Abdullah2, Peng-Cheng Ma3,4, Bekti Marlena1, Nanik Indah Setianingsih1, Dongsheng Song3,5 and Ali Moertopo Simbolon1 -- INTRODUCTION -- NATURE AND COMPOSITION OF PETROLEUM CRUDE OIL -- BIOREMEDIATION AGENTS -- Bacteria as Bioremediation Agents of Hydrocarbon Contaminated Environment -- Fungal Bioremediation of Hydrocarbon Contaminated Environment -- Algae as Bioremediation Agent of Hydrocarbon Contaminated Environment -- Commercialized Product of Microbial Agents for Hydrocarbon Remediation -- APPLICATION STRATEGIES AND PRACTICES -- In-situ Bioremediation -- Ex-situ Bioremediation -- FACTOR AFFECTING BIOREMEDIATION -- Temperature -- Substances Bioavailability -- Oxygen or Alternate Electron Acceptors -- Nutrients -- MATRICES TO BE REMEDIATED -- Soil Bioremediation -- Water Bioremediation -- Sludge Bioremediation -- CONCLUSION AND FUTURE CHALLENGES -- CONSENT FOR PUBLICATION -- CONFLICT OF INTEREST -- ACKNOWLEDGEMENT -- REFERENCES -- Bioremediation of Hydrocarbons -- Grace N. Ijoma1, Weiz Nurmahomed1, Tonderayi S. Matambo1, Charles Rashama1 and Joshua Gorimbo1,* -- INTRODUCTION -- Hydrocarbon Pollution Effects on Macrobiota -- Hydrocarbon Pollution Effects on Microbiota -- The Fate of Hydrocarbon Pollution in the Environment -- Weathering, Physical and Chemical Interactions with the Terrestrial Environment -- Weathering, Physical and Chemical Interactions within the Terrestrial Environment -- Reasons for Hydrocarbon Recalcitrance to Biodegradation -- Ecotoxicology: Consortia Stress Responses, Tolerance and Adaptation -- Rate-limiting Nutrients: Changes in Nitrogen Flux -- Changes in Microbial Population Dynamics. , Microbial Consortia Interactions Employed in the Degradation of Hydrocarbons.

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: Cover -- Half Title -- Title Page -- Copyright Page -- Contents -- Preface -- Editors -- Contributors -- Chapter 1: Semiconductor Optical Fibers -- Chapter 2: Optical Properties of Semiconducting Materials for Solar Photocatalysis -- Chapter 3: Semiconductor Optical Memory Devices -- Chapter 4: Semiconductor Optical Utilization in Agriculture -- Chapter 5: Nonlinear Optical Properties of Semiconductors, Principles, and Applications -- Chapter 6: Semiconductor Photoresistors -- Chapter 7: Semiconductor Photovoltaic -- Chapter 8: Progress and Challenges of Semiconducting Materials for Solar Photocatalysis -- Chapter 9: Linear Optical Properties of Semiconductors: Principles and Applications -- Chapter 10: Computational Techniques on Optical Properties of Metal-Oxide Semiconductors -- Index.

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.