Advanced ceramic coatings for emerging applications / Ram Gupta [and four others], editors.

Format:

Book

Contributor:

Gupta, Ram K., editor.

Series:

Elsevier Series on Advanced Ceramic Materials

Language:

English

Subjects (All):

Ceramic coating--Industrial applications.

Ceramic coating.

Ceramic coating--Technological innovations.

Ceramics.

Medical Subjects:

Ceramics.

Physical Description:

1 online resource (362 pages)

Place of Publication:

Amsterdam, Netherlands : Elsevier Ltd., [2023]

Summary:

Advanced Ceramic Coatings for Emerging Applications covers new developments in automotive, construction, electronic, space and defense industries. The book is one of four volumes that together provide a comprehensive resource in the field of Advanced Ceramic Coatings, also including titles covering fundamentals, manufacturing and classification, energy and biomedical applications. These books will be extremely useful for academic and industrial researchers and practicing engineers who need to find reliable and up-to-date information about recent progresses and new developments in the field of advanced ceramic coatings. These books will also be of value to early career scientists providing background knowledge to the field. Smart ceramic coatings containing multifunctional components are now finding application in transportation and automotive industries, in electronics, and energy, sectors, in aerospace and defense, and in industrial goods and healthcare. Their wide application and stability in harsh environments are only possible due to the stability of the inorganic components that are used in ceramic coatings.

Contents:

Front Cover

Advanced Ceramic Coatings for Emerging Applications

Copyright Page

Contents

List of contributors

1 Smart coatings and sensing applications

1 Ceramic material coatings: emerging future applications

1.1 Introduction

1.2 Ceramic coating in machining applications

1.3 Ceramic coating in aerospace applications

1.4 Ceramic coating in biomedical applications

1.5 Ceramic coating in the energy sector for structural applications

1.6 Ceramic coating in the semiconductor industry

1.7 Summary

References

2 Self-healing ceramic coatings

2.1 Introduction

2.2 Self-healing ceramic coatings

2.3 Design and exploration of self-healing ceramic coatings

2.4 Self-healing mechanism

2.5 Conclusion and future perspective

3 Self-cleaning ceramic coatings

3.1 Introduction

3.1.1 Basics of self-cleaning

3.2 The photocatalytic self-cleaning mechanism

3.2.1 Historical background of photocatalysis

3.2.2 Photocatalytic materials

3.2.3 Photocatalytic mechanisms

3.2.3.1 Silicon oxide nanoparticles

3.2.3.2 Zinc oxide nanoparticles

3.2.3.3 Titanium oxide nanoparticles

3.3 Wettability via surface roughness and porosity

3.4 The self-cleaning photocatalytic process

3.4.1 Titanium dioxide photocatalyst

3.4.2 Self-cleaning superhydrophilic surfaces: synthesis and fabrication

3.4.2.1 Sol-gel technique

3.4.2.2 Hydrothermal and solvothermal technique

3.4.2.3 Layer-by-layer technique

3.4.2.4 Electrochemical technique

3.4.2.5 Electrospinning technique

3.4.2.6 Plasma treatment

3.5 Self-cleaning coverings and their applications

3.5.1 Oil-water segregation and antifouling membranes in wastewater management

3.5.2 Antireflective coverings

3.5.3 Antimicrobial coatings

3.5.4 Self-cleaning textiles

3.5.5 Breathable coatings.

3.5.6 Coatings for construction material

3.5.7 Anticorrosive coverings

3.6 Limitations and the future prospects

3.7 Summary

3.8 Conclusion

4 Ceramics for sensing application

4.1 Introduction of ceramics

4.2 Ceramic sensors

4.3 Humidity sensors

4.3.1 Materials for humidity sensors

4.3.2 Types of humidity sensors

4.3.2.1 Thermal, capacitive, and resistive type sensors

4.3.2.2 Electrical humidity sensors

4.3.2.3 Electrochemical humidity sensors

4.3.2.4 Optical humidity sensors

4.3.2.5 Mass sensitive humidity sensors

4.4 Ceramic gas sensors

4.5 Porous ceramic sensors

4.6 Ceramic sensors in automobiles

4.7 Ceramic sensors in aviation

4.8 Ceramic sensors in medicine

2 High temperature and turbine applications

5 High-entropy ceramic coatings

5.1 Introduction

5.2 Design and fabication methods of high-entropy ceramic coatings

5.2.1 Feature and design of high-entropy ceramic coatings

5.2.2 Fabrication methods

5.3 History, composition, structure, and application of HEA ceramic coatings

5.3.1 High-entropy nitride

5.3.2 High-entropy oxide

5.3.3 High-entropy carbide

5.3.4 High-entropy boride

5.4 Conclusions and outlook

Acknowledgments

6 Ceramic coatings in turbine applications

6.1 Introduction to thermal barrier coatings

6.2 Preparation technologies and microstructure of thermal barrier coatings

6.3 Ceramic top coat materials for thermal barrier coating applications

6.3.1 Yttria-stabilized zirconia

6.3.2 Other doped ZrO2

6.3.3 Pyrochlores

6.3.4 Perovskites

6.3.5 Rare earth phosphates

6.4 Degradation of TBCs by CMAS

6.4.1 Discovery of CMAS issues

6.4.2 Corrosion mechanisms for TBCs by CMAS

6.4.3 Mitigation strategies for CMAS attack to TBCs

References.

7 Advanced ceramics coating composites with high corrosion resistance in oil and gas application

7.1 Literature review

7.2 Methodology

7.3 Results, analysis, and discussion

7.3.1 Microstructural analysis of the surface

7.3.2 Electrochemical corrosion analysis

7.3.3 Microstructural analysis of corrosion

7.4 Conclusion

8 Advanced thermal barrier coatings for aerospace gas turbine engine applications

8.1 Introduction

8.2 Coating processes used for thermal barrier coating

8.2.1 Plasma spray

8.2.1.1 Atmospheric plasma spray

8.2.1.2 Suspension plasma spray

8.2.1.3 Electron beam physical vapor deposition

8.3 Anatomy of thermal barrier coating

8.3.1 Bond coat

8.3.2 Thermally grown oxide

8.3.3 Top coat

8.4 Required properties of ceramic top coat

8.4.1 Conventional 7YSZ ceramic top coat: Properties and phase stability

8.4.2 Limitations of conventional 7YSZ ceramic top coat

8.5 Alternative ceramic top coat materials

8.5.1 CeO2+7YSZ

8.5.2 Mullite

8.5.3 Lanthanum aluminates

8.5.4 Perovskites

8.5.4.1 BaZrO3

8.5.4.2 SrZrO3

8.5.5 Dysprosia-stabilized zirconia

8.5.6 Ytterbia-stabilized zirconia

8.5.7 Pyrochlore

8.5.7.1 La2Zr2O7

8.5.7.2 Gd2Zr2O7

8.5.7.3 La2Ce2O7

8.6 Bilayered ceramic top coat

8.7 Failure modes of TBC

8.7.1 Phase instability

8.7.2 Sintering

8.7.3 Hot corrosion

8.7.4 Erosion

8.7.5 Infiltration of calcium magnesium alumino silicate

8.7.6 Thermal cycling failure

8.7.6.1 Increase of TGO thickness

8.7.6.2 Coefficient of thermal expansion mismatch

8.8 Summary

8.9 Future direction

3 Energy applications

9 Ceramic coating for electrostatic energy storage

9.1 Introduction

9.2 Theories

9.2.1 Electrostatic energy storage

9.2.2 Electrical conduction.

9.2.3 Electrical breakdown

9.2.4 Interface electronic band structure and surface states

9.3 Ceramic coatings

9.3.1 Hexagonal boron nitride

9.3.2 Oxides

9.3.3 Montmorillonite

9.4 Conclusions and prospects

10 Plasma-sprayed ceramic coatings for solid oxide fuel cells

10.1 Introduction to solid oxide fuel cells

10.2 Plasma spray technique

10.3 Metal-supported solid oxide fuel cells

10.4 Literature on plasma-sprayed solid oxide fuel cell components

10.4.1 Metal-supported solid oxide fuel cell

10.4.1.1 Electrolyte

10.4.1.2 Cathode

10.4.1.3 Anode

10.4.1.4 Complete cell

10.4.2 Interconnect and bipolar plate protective coatings for ASC and ESC

10.4.2.1 Strontium-doped lanthanum manganite coatings

10.4.2.2 Mn-Co and Mn-Cu-based spinel coatings

10.4.2.3 Other oxides

10.5 Conclusions

11 CuInxGa1-xS2 absorber material for thin-film solar cells

11.1 Introduction

11.2 Working principle of a solar cell

11.3 Solar cell: absorber materials

11.4 Evolution of the CIGS absorber layer

11.4.1 Current status

11.5 Device structure and band alignment of CuInxGa1-x(S, Se)2

11.6 Crystallographic structure and phase diagram

11.6.1 Defects in CuInxGa1-xSe2

11.7 Optical properties of CIGS

11.8 Processing of the CIGS absorber layer

11.8.1 Physical vapor deposition

11.8.2 Solution-based deposition

11.9 Performance of a solar cell

11.10 Conclusion and outlook

4 Health care applications

12 A study on the effect of AlTiN and TiCN coatings on the tribological properties of dental drills

12.1 Introduction

12.2 Materials and methods

12.3 Results and discussion

12.3.1 Microstructure of AlTiN and TiCN nanocomposite films

12.3.2 Mechanical and tribological properties of coatings.

12.3.3 Temperature measurement during the drilling process

12.3.4 Electrochemical corrosion tests

12.3.5 Autoclave sterilization resistance

12.4 Conclusion

Acknowledgment

13 Bioceramic coatings for tissue engineering

13.1 Introduction

13.2 Classification of bioceramics

13.2.1 Bioinert ceramics

13.2.1.1 Alumina

13.2.1.2 Zirconia

13.2.1.3 Zirconia-alumina composites

13.2.2 Bioactive glass and glass ceramics

13.2.3 Calcium phosphate bioceramics

13.3 Coating methods

13.3.1 Sol-gel

13.3.1.1 Titania films and coatings

13.3.1.2 Hydroxyapatite

13.3.2 Dip coating

13.3.3 Spin coating

13.3.4 Electrochemical deposition

13.4 Applications of bioceramic coatings

13.4.1 Bioinert ceramics coatings for tissue engineering

13.4.2 Bioactive glass and glass ceramics for tissue engineering

13.4.3 Calcium phosphate bioceramics for tissue engineering

13.4.4 Metal ion-doped bioceramics for tissue engineering

13.4.5 Polymer bioceramic biocomposites for tissue engineering

13.5 Challenges and future perspectives

14 Ceramic coatings for wound healing applications

14.1 Introduction

14.2 Biological significance of ceramics

14.2.1 Ceramics as an antibacterial agent

14.2.2 Ceramics as drug carriers

14.2.3 Ceramics as nanofiller

14.2.4 Ceramics as dressing materials

14.3 Techniques for ceramic coatings

14.3.1 Sol-gel

14.3.2 Dynamic mixing

14.3.3 Dip coating

14.3.4 Electrochemical deposition

14.3.5 Plasma spraying

14.4 Wound healing applications

14.4.1 Nanomaterial based ceramic coatings in wound healing

14.4.2 Polymer-ceramic composite coating in wound healing

14.4.3 Carbon-based ceramic coating in wound healing

14.5 Conclusion and future perspective

Index

Back Cover.

Notes:

Includes bibliographical references and index.

Description based on print version record.

Other Format:

Print version: Gupta, Ram Advanced Ceramic Coatings for Emerging Applications

ISBN:

9780323996259

0323996256