Surface Modification and Functionalization of Ceramic Composites

1st Edition - March 23, 2023
Editors: Rajan Jose, Fabian Ezema
Language: English
Paperback ISBN:
9 7 8 - 0 - 3 2 3 - 8 5 8 8 3 - 0
eBook ISBN:
9 7 8 - 0 - 3 2 3 - 8 9 7 8 7 - 7
eBook ISBN:
9 7 8 - 0 - 3 2 3 - 8 5 5 7 3 - 0

Surface Modification and Functionalization of Ceramic Composites is intended for both experts and beginners, allowing them to have an extended overview of recent progress in the ev… Read more

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Surface Modification and Functionalization of Ceramic Composites is intended for both experts and beginners, allowing them to have an extended overview of recent progress in the evolution of surface modification methods and functionalization for ceramic composites. The book provides a detailed summary of the various techniques that are currently available, along with an evaluation of the costs involved. Information on the relationship between surface properties and function is also discussed. There is also an additional section on commercial and industrial applications, including biomedical, sensing and energy.

The book will be a valuable reference resource for researchers and an instructive and stimulating text for postgraduate students who want to enhance their knowledge on novel materials and surface modification and functionalization of ceramic composites.

Cover
Title page
Table of Contents
Copyright
Dedication
Contributors
Preface
1: Introduction: Review of the status of modification and functionalization of ceramic composites, progress, and perceptions
Abstract
1.1: Introduction
1.2: Classifications of ceramics
1.3: Ceramic composites fabrication techniques
1.4: Conclusion
References
2: Surface modification of zirconia ceramics using polymer surface modification and functionalization of ceramics composites
Abstract
2.1: Introduction
2.2: Surface modifications of zirconia ceramics
2.3: Conclusion
References
3: Surface modification and functionalization of ceramic composite using self-assembled monolayer and graft polymerization
Abstract
3.1: Introduction
3.2: Self-assembled monolayers (SAMs)
3.3: Structure of SAMs
3.4: SAMs preparation
3.5: SAMs characterization
3.6: Kinetics involved in SAMs formation
3.7: SAMs growth rate
3.8: Factors affecting monolayer embedded functional groups’ reactivity
3.9: Defects in SAMs
3.10: SAMs patterning
3.11: Advantages of SAMs
3.12: Graft polymerization
3.13: Strategies involved in graft polymerization
3.14: Steps involved in the surface modification by graft polymerization
3.15: Structure of grafted surfaces
3.16: Factors affecting grafting efficiency
3.17: Problems encountered in graft polymerization
3.18: Advantages of graft polymerization
3.19: Conclusion
References
4: Improving the catalytic properties of ceramics—CNT composites by carbon nanotubes (CNTs) surface modification
Abstract
4.1: Introduction
4.2: Experimental
4.3: Results and discussion
4.4: Conclusions
References
5: Effect of surface modification on the dielectric properties of mixed transition metal oxides ceramics composites
Abstract
5.1: Introduction
5.2: Structures of MTMOs ceramics
5.3: Basis of surface modification and its effect in dielectric properties of MTMO ceramics composites
5.4: Conclusion
References
6: Enhancement of ceramics applications using a surface modification of coated various deposition techniques in ceramics composites
Abstract
6.1: Introduction
6.2: Concepts of ceramics coatings
6.3: Conclusion
References
7: Effects of surface modification (surface treatment) on friction and surface abrasion of ceramic composites
Abstract
7.1: Introduction
7.2: Ceramic composites
7.3: Friction and abrasion of ceramic composite system
7.4: Surface modification of ceramic composites
7.5: Conclusions
References
8: Synthesis, characterization, and dielectric properties of surface-functionalized ferroelectric ceramic composites
Abstract
8.1: Introduction
8.2: Materials for the functionalization of ferroelectric ceramics
8.3: Interfacial interaction of functionalized ferroelectric ceramics
8.4: Fabrication of ferroelectric ceramic-polymer–based composites
8.5: Characterization of ferroelectric ceramic-polymer–based composites
8.6: Dielectric properties of ferroelectric ceramic-polymer–based composites
8.7: Challenges, recommendations, and applications
8.8: Conclusion
References
9: Surface modification and functionalization of ceramics composites with cellulose materials
Abstract
Acknowledgment
9.1: Introduction
9.2: Cellulose
9.3: Cellulose-reinforced ceramic composites
9.4: Uses, techniques, and challenges of surface modification of ceramics with cellulose
9.5: Prospects of cellulose-reinforced ceramic composites
9.6: Conclusion and recommendations
References
10: Application of upconversion nanoparticles (UCNPs) as nano-ceramic materials for bioimaging
Abstract
10.1: Introduction: Upconversion nanoparticles (UCNPs)
10.2: Upconversion (UC) process
10.3: Lanthanides-based upconversion nanoparticles (UCNPs)
10.4: Components of lanthanide upconversion nanoparticles
10.5: Synthesis techniques
10.6: Surface modification and functionalization
10.7: Applications of upconversion nanoparticles as ceramic composites
References
11: Synthesis and fabrication of cathodic electrophoretic deposition of ceramic materials and composites using extracted dyes from different plants
Abstract
11.1: Introduction
11.2: Electrophoretic deposition of ceramic materials
11.3: Electrophoretic deposition of ceramic materials along with their composites using extracted dyes from different plants
11.4: Catechol family of dyes for EPD
11.5: Cathodic EPD applying celestine blue dye
11.6: Conclusion
References
12: Functionalized ceramic matrix composites: Fabrication, application, and recycling
Abstract
12.1: Introduction
12.2: Classification
12.3: The classification of campsite materials based on matrix phase
12.4: The classification of campsite materials based on reinforcements
12.5: The classification of campsite materials based on the scale
12.6: Methods of synthesis
12.7: Distinct properties
12.8: Recycling
12.9: Application
12.10: Conclusion
References
13: Overview of electrical discharge coating technique of surface modification and functionalization of ceramic composites
Abstract
Acknowledgments
13.1: Introduction
13.2: Basics of electric discharge coating
13.3: Working principle of EDC in surface modification technique
13.4: EDCs factors
13.5: Features of EDCs coats
13.6: EDC applications
13.7: Conclusion
References
14: Surface modification and functionalization of ceramic composites for bone implantation
Abstract
14.1: Introduction
14.2: Ceramic materials used for bone implantations
14.3: Surface modification and functionalization of biomaterials
14.4: Conclusion
References
15: Ceramic-based functional electrode materials for application in solid oxide cell-based electrochemical devices
Abstract
Graphical abstract
15.1: Introduction
15.2: Functional air electrodes for SOCs
15.3: Functional fuel electrodes for SOCs
15.4: Application of “ab initio” first principle toward functionalization of electrodes
15.5: Conclusion and remarks on future direction
References
16: Surface modification of calcium phosphate scaffolds with antimicrobial agents for bone tissue engineering
Abstract
Acknowledgments
16.1: Introduction
16.2: Scaffolds for bone tissue engineering
16.3: Osteomyelitis and bone tissue engineering
16.4: Antimicrobial agents
16.5: Antimicrobial evaluation methods
16.6: Antimicrobial scaffolds
16.7: Case study
16.8: Conclusions
References
17: Surface modification of multifunctional zinc ferrite nanocomposites for biomedical applications
Abstract
17.1: Introduction
17.2: Surface modification of zinc ferrite nanocomposite
17.3: Biomedical applications zinc ferrite nanocomposite
17.4: Conclusion
References
18: The role of ceramic composite materials in achieving next-generation electrochemical energy storage devices
Abstract
Acknowledgments
18.1: Introduction
18.2: Ceramic-based separators for secondary batteries
18.3: Concerns in existing electrochemical energy storage systems
18.4: Outlook, challenges, and prospects of polymer-derived ceramics as electrochemical energy storage systems
18.5: The role of ceramic composite materials in achieving the next-generation electrochemical energy storage devices
References
19: Ceramic-polyaniline composites for asymmetric supercapacitors
Abstract
19.1: Introduction
19.2: Conducting polymers for supercapacitors
19.3: Utility of PANi-based nanocomposites as supercapacitor electrodes
19.4: Ceramic/PANI composites for asymmetric supercapacitor (ASC)
19.5: Conclusion
References
20: Fabrication of duplex-layer coating on metallic implants: Advanced surface modification of metallic implants for orthopedic applications
Abstract
Acknowledgments
20.1: Introduction
20.2: Materials and methods
20.3: Results and discussion
20.4: Conclusions
References
21: Surface modification of borate composite for dosimetric application
Abstract
21.1: Introduction
21.2: Processing technique of thermoluminescence borates
21.3: Mechanism of thermoluminescence
21.4: Applications of borate TL materials in dosimetry
21.5: Conclusion
References
22: Piezoelectric and dielectric properties of phase-re-engineered barium titanate prepared by self-propagating high-temperature synthesis
Abstract
22.1: Introduction
22.2: Experimental
22.3: Results and discussion
22.4: Conclusion and future outlook
References
23: Density functional theory (DFT) simulation and approach to property-driven investigations in ceramic and composites materials
Abstract
23.1: Introduction
23.2: Why density functional theory (DFT)?
23.3: A brief overview of the basic density theory concepts
23.4: Some examples of DFT applications in ceramics and composites
23.5: Conclusions
References
Index

Life Sciences

Physical Sciences & Engineering

Social Sciences & Humanities

Health

Surface Modification and Functionalization of Ceramic Composites

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Rajan Jose

Fabian Ezema