Functionalized Nanomaterial-Based Electrochemical Sensors
Principles, Fabrication Methods, and Applications
- 1st Edition - January 11, 2022
- Imprint: Woodhead Publishing
- Editors: Jamballi G. Manjunatha, Chaudhery Mustansar Hussain
- Language: English
- Paperback ISBN:9 7 8 - 0 - 1 2 - 8 2 3 7 8 8 - 5
- eBook ISBN:9 7 8 - 0 - 1 2 - 8 2 4 1 8 5 - 1
Functionalized Nanomaterial-Based Electrochemical Sensors: Principles, Fabrication Methods, and Applications provides a comprehensive overview of materials, functiona… Read more
Purchase options
Institutional subscription on ScienceDirect
Request a sales quoteFunctionalized Nanomaterial-Based Electrochemical Sensors: Principles, Fabrication Methods, and Applications provides a comprehensive overview of materials, functionalized interfaces, fabrication strategies and application areas. Special attention is given to the remaining challenges and opportunities for commercial realization of functionalized nanomaterial-based electrochemical sensors. An assortment of nanomaterials has been investigated for their incorporation into electrochemical sensors. For example, carbon- based nanomaterials (carbon nanotube, graphene and carbon fiber), noble metals (Au, Ag and Pt), polymers (nafion, polypyrrole) and non-noble metal oxides (Fe2O3, NiO, and Co3O4). The most relevant materials are discussed in the book with an emphasis on their evaluation of their realization in commercial applications.
Application areas touched on include the environment, food and medicine industries. Health, safety and regulation considerations are touched on, along with economic and commercialization trends.
- Introduces the principles of nanomaterials for electrochemical sensing applications
- Reviews the most relevant fabrication strategies for functionalized nanomaterial-based electrochemical sensing platforms
- Discusses considerations for the commercial realization of functionalized nanomaterial-based electrochemical sensors in the environment, food and point-of-care applications
Materials Scientists and Engineers
- Cover
- Title page
- Table of Contents
- Copyright
- Contributors
- Preface
- Section A: Modern perspective in electrochemical-based sensors: Functionalized nanomaterials (FNMs)
- 1: Functionalized nanomaterial-based electrochemical sensors: A sensitive sensor platform
- Abstract
- 1.1: Introduction
- 1.2: Quantum-Dot nanomaterial
- 1.3: Gold nanoparticles
- 1.4: Carbon-based materials
- 1.5: Multiwalled nanotubes
- 1.6: Graphene
- 1.7: Carbon nanoparticle-based electrochemical sensor
- 1.8: Magnetic nanoparticles
- 1.9: Zinc oxide nanotubes
- 1.10: Nickel oxide nanoparticles and carbon black
- 1.11: Conclusion
- References
- 2: Recent progress in the graphene functionalized nanomaterial-based electrochemical sensors
- Abstract
- 2.1: Introduction
- 2.2: Advantages of graphene-based biosensor
- 2.3: Preparation of graphene-based biosensor
- 2.4: Graphene biosensor for glucose and dopamine
- 2.5: DNA-based biosensing
- 2.6: Graphene biosensor for protein biomarkers
- 2.7: Hb biosensor
- 2.8: Cholesterol biosensor
- 2.9: GN based biosensor for bacteria
- 2.10: Conclusion
- References
- Section B: Fabrication of functionalized nanomaterial-based electrochemical sensors platforms
- 3: Application of hybrid nanomaterials for development of electrochemical sensors
- Abstract
- 3.1: Introduction
- 3.2: SiO2/MWCNTs, SiO2/MWCNTs/AgNPS, and GO/Sb2O5
- 3.3: Carbon dots/Fe3O4 and rGO/carbon dots
- 3.4: rGO/carbon dots/AuNPs
- 3.5: Conclusion
- Websites
- References
- 4: Biofunctionalization of functionalized nanomaterials for electrochemical sensors
- Abstract
- 4.1: Introduction
- 4.2: Biosensors
- 4.3: Conclusion
- References
- Section C: Functionalized carbon nanomaterial-based electrochemical sensors
- 5: Functionalized carbon nanomaterials in electrochemical detection
- Abstract
- 5.1: Introduction
- 5.2: Functionalization of carbon materials
- 5.3: Applications of functionalized carbon materials in electrochemical biosensors
- References
- 6: Functionalized carbon material-based electrochemical sensors for day-to-day applications
- Abstract
- 6.1: Introduction
- 6.2: Electrochemical biosensors
- 6.3: Supercapacitors
- 6.4: Gas sensors
- 6.5: Wearable electronic devices
- 6.6: Piezoelectric sensors
- 6.7: Conclusion
- References
- Section D: Noble metals, non-noble metal oxides and non-carbon-based electrochemical sensors
- 7: Noble metals and nonnoble metal oxides based electrochemical sensors
- Abstract
- 7.1: Introduction
- 7.2: Synthesis of noble metal and nonnoble metal nanoparticles
- 7.3: Noble metal-based electrochemical sensors
- 7.4: Nonnoble metal oxides based electrochemical sensors
- 7.5: Conclusion
- References
- Section E: Functionalized nanomaterial-based electrochemical based sensors for environmental applications
- 8: Functionalized nanomaterial-based environmental sensors: An overview
- Abstract
- 8.1: Introduction
- 8.2: Noble metal nanomaterials
- 8.3: Metal oxide nanomaterials
- 8.4: Carbon nanomaterials
- 8.5: Polymer nanomaterials
- 8.6: Conclusions and perspectives
- References
- 9: Advantages and limitations of functionalized nanomaterials based electrochemical sensors environmental monitoring
- Abstract
- 9.1: Introduction
- 9.2: Advantages
- 9.3: Limitations
- 9.4: Conclusions and future outlooks
- References
- Section F: Functionalized nanomaterial-based electrochemical sensors technology for food and beverages applications
- 10: Attributes of functionalized nanomaterial-based electrochemical sensors for food and beverage analysis
- Abstract
- 10.1: Introduction
- 10.2: Properties of electrochemical sensor in food and beverage analysis
- 10.3: EC sensors based on functionalized nanomaterials
- 10.4: Additives and contaminants
- 10.5: Pesticides
- 10.6: Conclusion and future perspective
- References
- 11: The use of FNMs-based electrochemical sensors in the food and beverage industry
- Abstract
- Graphical abstract
- 11.1: Introduction
- 11.2: Food and beverage contamination
- 11.3: Functionalized nanomaterials for sensing in the food and beverage industry
- 11.4: Conclusions and perspectives
- References
- 12: Trends in functionalized NMs-based electrochemical sensors in the food and beverage industry
- Abstract
- 12.1: Introduction
- 12.2: Sensor applications of NMs in the food industry
- 12.3: Reliability problems of NMs for electrochemical sensor applications in food analysis
- 12.4: Conclusion
- References
- Section G: Functionalized nanomaterial-based electrochemical sensors for point-of-care applications
- 13: Functionalized nanomaterial-based medical sensors for point-of-care applications: An overview
- Abstract
- 13.1: Introduction
- 13.2: 0D (spherical) nanomaterials
- 13.3: One-dimensional nanomaterials
- 13.4: Two-dimensional nanomaterials
- 13.5: Three-dimensional nanomaterials
- 13.6: Conclusion and future perspective
- References
- 14: Functionalized nanomaterial- based electrochemical sensors for point-of-care devices
- Abstract
- Acknowledgment
- 14.1: Introduction
- 14.2: Electrochemical sensors
- 14.3: Applications of electrochemical sensors
- 14.4: The use of functionalized nanomaterials-based electrochemical sensors in point-of-care diagnostics
- 14.5: Conclusions
- References
- 15: Current trends of functionalized nanomaterial-based sensors in point-of-care diagnosis
- Abstract
- 15.1: Introduction
- 15.2: Methods of functionalization of nanomaterials
- 15.3: Point-of-care diagnostics
- 15.4: Conclusion
- References
- Section H: Health, safety, and regulations issues of functionalized nanomaterials
- 16: Current status of environmental, health, and safety issues of functionalized nanomaterials
- Abstract
- 16.1: Introduction
- 16.2: Environmental health and hazards
- 16.3: Opportunities and challenges
- References
- 17: Functionalized metal and metal oxide nanomaterial-based electrochemical sensors
- Abstract
- 17.1: Introduction to sensors
- 17.2: Working principle and classification of electrochemical sensors
- 17.3: Applications of electrochemical sensors
- 17.4: Carbon nanomaterials-based electrochemical sensors
- 17.5: Metallic nanoparticles based electrochemical sensors
- 17.6: Metallic oxide nanoparticles based electrochemical sensors
- 17.7: Conclusion
- 17.8: Challenges and prospects
- References
- 18: Functionalized nanomaterials and workplace health and safety
- Abstract
- 18.1: Introduction
- 18.2: Functionalized nanomaterials
- 18.3: Conclusion
- References
- 19: Layer-by-layer nanostructured films for electrochemical sensors fabrication
- Abstract
- Acknowledgments
- 19.1: Introduction
- 19.2: Layer-by-layer technique
- 19.3: LbL electrochemical sensors
- 19.4: LbL electrochemical biosensors
- 19.5: Final remarks
- References
- Section I: Economics and commercialization of functionalized nanomaterial-based electrochemical sensors
- 20: Fabrication of functionalized nanomaterial-based electrochemical sensors’ platforms
- Abstract
- 20.1: Introduction
- 20.2: Environmental sensors
- 20.3: Cell-based sensor
- 20.4: COVID-19 biosensors
- References
- 21: Advantages and limitations of functionalized graphene-based electrochemical sensors for environmental monitoring
- Abstract
- 21.1: General aspects
- 21.2: Graphene functionalization
- 21.3: Functionalized graphene-based electrochemical sensors
- 21.4: Environmental applications
- 21.5: Concluding remarks and perspectives
- References
- 22: TiO2 nanotube arrays grafted with metals with enhanced electroactivity for electrochemical sensors and devices
- Abstract
- 22.1: Introduction
- 22.2: TiO2 nanotubes
- 22.3: Grafting of noble metals and nonnoble materials on anodic TiO2 nanotubes
- 22.4: Electrochemical applications of metal/TiO2 NTs based sensors
- 22.5: Summary and outlook
- References
- Section J: Future of functionalized nanomaterial-based electrochemical sensors
- 23: Functionalized carbon nanomaterial-based electrochemical sensors: Quick look on the future of fitness
- Abstract
- 23.1: Introduction
- 23.2: Carbon-nanotube-based electrochemical sensors
- 23.3: Graphene-based electrochemical sensors
- 23.4: Carbon nanodots
- 23.5: Other carbon functional materials
- 23.6: Carbon nanomaterials in wearable sensors and future scope
- References
- Index
- Edition: 1
- Published: January 11, 2022
- Imprint: Woodhead Publishing
- No. of pages: 610
- Language: English
- Paperback ISBN: 9780128237885
- eBook ISBN: 9780128241851
JM
Jamballi G. Manjunatha
J G Manjunatha is an Assistant Professor in Chemistry at FMKMC College, A Constituent College of Mangalore University, India. He received his Ph.D. degree in Chemistry from Kuvempu University and Postdoc from the University of Kebangsaan Malaysia. His research interests focus on the fabrication of electrochemical sensors for the detection of biologically active molecules and the fabrication of binderless supercapacitors. He has received various awards and published more than 190 research articles in reputed International Journals. An editor for around 21 books books (RSC, ACS, IOP, Elsevier and Bentham science publishers), and special issues (IOP Science Publisher, Frontiers in Sensors, MDPI). He is also an editorial board member for many reputed journals and Editor -Chief Sensing technology journal (Taylor and Francis).
Affiliations and expertise
Assistant Professor in Chemistry, FMKMC College Madikeri, Mangalore University, IndiaCM
Chaudhery Mustansar Hussain
Dr. Chaudhery Mustansar Hussain, PhD, is an Adjunct Professor and Director of Laboratories in the Department of Chemistry & Environmental Sciences at the New Jersey Institute of Technology (NJIT), Newark, New Jersey, United States. His research is focused on the applications of nanotechnology and advanced materials, environmental management, analytical chemistry, and other various industries. Dr. Hussain is the author of numerous papers in peer-reviewed journals as well as a prolific author and editor of around One hundred and fifty (150) books, including scientific monographs and handbooks in his research areas. He has published with ELSEVIER, American Chemical Society, Royal Society of Chemistry, John Wiley & Sons, CRC Press, and Springer.
Affiliations and expertise
Adjunct Professor & Director of Laboratories, New Jersey Institute of Technology (NJIT), Newark, NJ, USARead Functionalized Nanomaterial-Based Electrochemical Sensors on ScienceDirect