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Emerging Nanomaterials for Catalysis and Sensor Applications

✍ Scribed by Varghese A., Hegde G. (ed.)

Publisher
CRC Press
Year
2023
Tongue
English
Leaves
299
Series
Emerging Materials and Technologies
Category
Library
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✦ Synopsis

This book reviews emerging nanomaterials in catalysis and sensors. The catalysis section covers the role of nano-photocatalysts in organic synthesis and health care application, oxidation and sulphoxidation reactions, liquid phase oxidation, hydrogen evolution and environmental remediation. It highlights the correlation of surface properties and catalytic activity of the mesoporous materials. The sensor section discusses the fabrication and development of various electrochemical, chemical, and biosensors.
Features:
Combines catalysis and sensor applications of nanomaterials, including detailed synthesis techniques of these materials.
Explores methods of designing, engineering, and fabricating nanomaterials.
Covers material efficiency, their detection limit for sensing different analytes and other properties of the materials.
Discusses sustainability of nano materials in the industrial sector.
Includes case studies to address the challenges faced by research and development sectors.
This book is aimed at researchers and graduate students in Chemical Engineering, Nanochemistry, Water Treatment Engineering and Labs, Industries, Research Labs in Catalysis and Sensors, Environmental Engineering, and Process Engineering.

✦ Table of Contents

Cover
Half Title
Emerging Materials and Technologies Series
Emerging Nanomaterials for Catalysis and Sensor Applications
Copyright
Contents
Editor Biographies
Contributors
Section I: Emerging Materials in Nanocatalysis
1. The Role of Nanomaterials in Sustainable Organic Synthesis
1.1 Nanomaterial as Catalysts
1.2 Characteristics of Nanomaterials
1.3 Properties of Nanomaterials as Catalysts
1.4 Nanocatalyst in Organic Transformations
1.5 Recent Developments in Advanced Nanocatalysts
1.6 Nanostructured Catalysts for Greener and Sustainable Organic Processes
1.7 Outlook
References
2. Nanocatalysts in Oxidation and Sulfoxidation Reactions
2.1 Sulfur Redox Reactions
2.1.1 Sulfur Electrochemistry in Li–S Batteries
2.1.2 Liquid Sulfur-Redox Reaction
2.2 Molybdenum Catalyst Used for Sulfoxidation Reactions in Aqueous Medium
2.2.1 Characterization of Molybdenum Catalyst
2.3 TiO2 Catalyst for Enantioselective Sulfoxidation
2.4 Selective Oxidation of Alkylsulfides
2.5 Applications of Nanocatalyst
2.5.1 Use in Environment and Especially in Wastewater Treatment
2.5.2 Applications of Nanocatalyst in Mechanical Industries
2.5.3 Applications of Nanocatalyst in Drugs Delivery
2.5.4 Energy Harvesting Applications
2.5.5 Materials Engineering Applications
2.6 Nickel Nanocatalyst in the Enhancement of Hydrogen Oxidation Reactions
2.6.1 Ni@h- BN Nanocatalyst Characterization
2.7 Organic and Inorganic Hybrid Nanocatalyst for Oxidation Reaction
2.7.1 Characterization of Ag- HAp Catalyst
2.8 Metal Organic Frameworks as Oxidation Catalyst
2.9 Metals as Heterogeneous Catalysts for Different Oxidation Reactions
2.9.1 The Conversion of Glucose to Gluconic Acid
2.9.2 The Oxidative Conversion of Hydrogen to Hydrogen Peroxide
2.9.3 The Oxidation of Alcohols
References
3. Correlation of Surface Properties and Catalytic Activity of Metal Aluminophosphates
3.1 Introduction to Alumina- Based Porous Materials
3.1.1 Aluminophosphates (AlPO)
3.2 Synthesis of Alumina-Based Materials
3.2.1 Preparation of Amorphous Mesoporous Metal Aluminophosphates
3.3 Characterization of Amorphous Mesoporous Aluminophosphates
3.3.1 Powder X-Ray Diffraction
3.3.2 X-Ray Diffraction Pattern of Aluminophosphates
3.3 Fourier Transform Infrared Spectroscopy (FTIR)
3.3.4 BET-Specific Surface Area
3.3.5 Temperature Programmed Desorption
3.3.6 X-Ray Photoelectron Spectroscopy
3.3.7 Raman Spectra
3.4 Correlation of Surface Properties On Catalytic Activity of Aluminophosphates
References
4. Carbon Supported Noble Metal Nanocatalysts for Liquid Phase Oxidation Reactions
4.1 Overview of Carbon Materials as Catalyst Supports
4.1.1 Liquid Phase Oxidation of Organic Compounds On Carbon-Supported Noble Metal Catalysts
4.1.2 Platinum and Palladium Nanocatalysts
4.1.3 Ruthenium Nanocatalysts
4.1.4 Gold and Silver Nanocatalysts
References
5. Metal Oxide Nanomaterials for Visible Light Photocatalysis
5.1 Introduction
5.2 Visible Light Photocatalysis
5.3 Mechanism of Photocatalysis
5.4 Various Types of Visible Light-Absorbing Photocatalysts
5.4.1 Modified Single Materials
5.4.2 Heterojunctions
5.4.3 Z-Scheme Heterojunctions
5.4.4 Carbon-Semiconductor Composites
5.4.5 Plasmonic Materials
5.4.6 Sensitized Photocatalysts
5.5 TiO2 Based Visible Light Active Metal Oxide Photocatalysts
5.5.1 TiO2 Structure, Properties and Electronic Processes
5.5.2 Advanced TiO2 Nanomaterials for Visible-Light Induced Applications
5.6 Non TiO2 Based Visible Light Photocatalysts
5.6.1 WO3 Based Photocatalysts
5.6.2 Bismuth-Based Photocatalysts
5.6.3 MoS2 Based Visible Light Active Photocatalysts
5.6.4 Ag3PO4 Based Nanocomposites
5.7 Applications of Metal Oxides for Visible Light-Induced Photocatalysis
5.7.1 Environmental Applications
5.7.2 Energy Applications
5.7.3 Synthetic Applications
5.8 Future Outlook and Conclusion
References
6. Progress in Photocatalysis for Hydrogen Evolution and Environmental Remediation
6.1 Introduction
6.2 Synthesis of Photocatalysts
6.2.1 Sol-Gel Process
6.2.2 Hydrothermal Process
6.2.3 Sonochemical Method
6.2.4 Chemical Vapor Deposition (CVD)
6.2.5 Physical Vapor Deposition (PVD)
6.2.6 Electrochemical Deposition
6.3 Reforms in Photocatalysis
6.3.1 Doping of Metals Or Non-Metals
6.3.2 Loading of Cocatalysts
6.3.3 Heterojunction Structures
6.4 Application
6.4.1 Hydrogen Evolution
6.4.2 Waste-Water Treatment
6.5 Conclusions and Future Prospective
References
Section II: Emerging Materials in Nanosensors
7. Nanostructured Materials for Sensors Applications
7.1 Introduction: Background and Driving Forces
7.2 Synthesis of Nanostructured Materials
7.2.1 2D Layered Inorganic Nanomaterials for Sensor Applications
7.2.1.1 Transition Metal Dichalcogenides (TMDs) as Sensor Materials
7.2.1.2 Synthesis of 2D Inorganic Materials for Sensor Applications
7.2.1.3 Metal Oxides as Sensor Materials
7.2.1.4 Synthesis of Metal Oxide Materials for Sensor Applications
7.2.2 Carbon and Its Allotropy Materials for Sensor Applications
7.2.2.1 Carbon and Graphene Quantum Dots as Sensors
7.2.2.2 Synthetic Methods of CQDs and GQDs and Application as Sensor Materials
7.2.2.3 Preparation of Carbon Quantum Dots (CQD) for Sensor Applications
7.2.2.4 Preparation of Graphene Quantum Dots (GQD) for Sensor Applications
7.2.3 Conducting Polymer (CP) Materials for Sensor Applications
7.2.3.1 Synthesis of Conducting Polymers (CPs) for Sensor Applications
7.2.4 Organic-Inorganic Hybrid Nanomaterials for Sensor Applications
7.2.4.1 Perovskites as Sensors
7.2.4.2 Synthesis of Perovskites Materials for Sensor Applications
7.2.4.3 Metal Organic Frameworks (MOFs) as Sensors
7.2.4.4 Synthesis of MOFs for Sensor Applications
7.3 Sensor Device Fabrications
7.4 Sensing Mechanism
7.5 Outlook
Acknowledgments
References
8. Synthesis of Fluorescent Nanosensor for Biomedical Engineering
8.1 Introduction
8.2 Preparation of Fluorescent Nanosensor
8.2.1 Hydrothermal Synthesis
8.2.2 Solvothermal Method
8.2.3 Ultrasonic Irradiations
8.2.4 Microwave Irradiation
8.2.5 Precipitation and Coprecipitation
8.2.6 Polymerization
8.3 Types of Fluorescent Nanosensor
8.3.1 PH-Sensitive Nanosensor
8.3.2 Temperature-Sensitive Nanosensor
8.3.3 Protease-Sensitive Nanosensor
8.3.4 Oxygen-Sensitive Nanosensor
8.4 Applications of Fluorescent Nanosensor
8.4.1 Detection of Microorganisms
8.4.2 Detection of Metallic and Nonmetallic Ions
8.4.3 Detection of Organic Compounds
8.4.3.1 Detection of Amino Acids, Proteins and Vitamins
8.4.3.2 Detection of Drugs
8.5 Future Perspectives
8.6 Conclusion
References
9. Applications of Peptide Luminescent Nanosensors
9.1 The Advent of Sensors and Nanosensors: Impact On Society
9.2 Classification of Nanosensors
9.3 Optical Nanosensors; Luminescent Nanosensors
9.4 Mechanisms of Operation of Luminescent Peptide Nanosensors
9.5 Future Perspectives of Peptide Nanosensors
9.6 Acknowledgments
References
10. Graphene-Based Hybrid Nano Composites for Bio/Chemical Sensors
10.1 Introduction
10.1.1 History of Graphene and Its Derivatives
10.1.2 Graphene Oxide (GO)/Reduced Graphene Oxide (RGO) Hybrid With Metal (M)/Metal Oxide (MO) Nano Structures
10.1.3 Sensors
10.1.4 Surface Enhanced Raman Spectroscopy (SERS) Based Sensors
10.1.5 Electrochemical Sensors
10.2 Types of GO/rGO Hybrid M/MO Nanocomposites
10.2.1 GO/rGO-Au Hybrid Nanocomposites
10.2.2 GO/rGO-Ag Hybrid Nanocomposites
10.2.2.1 GO/rGO–Os Hybrid Nanocomposites
10.2.3 GO/rGO-Cu Hybrid Nanocomposites
10.2.4 GO/rGO-ZnO Hybrid Nanocomposites
10.2.5 GO/rGO-SnO2 Hybrid Nano Composites
10.2.6 GO/rGO-Fe2O3 Hybrid Nanocomposites
10.3 Summary
References
11. Nanomaterial-Based Electrochemical Sensors for Vitamins and Hormones
11.1 Introduction
11.2 Nanomaterials – Principle and Conduction Properties for Electrochemical Sensing
11.3 Electrochemical Sensors for Water-Soluble Vitamins
11.4 Electrochemical Sensors for Hormone
11.5 Conclusions and Future Perspectives
References
12. Economic Analysis, Environmental Impact, Future Prospects and Mechanistic Understandings of Nanosensors and Nanocatalysis
12.1 Introduction
12.2 Economic Analysis of Nanosensors and Nanocatalysts
12.3 Environmental Impact of Nanosensors and Nanocatalysts
12.4 Mechanistic Understanding
12.5 Future Outlook
12.6 Conclusion
12.7 Acknowledgment
References
Index

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