Luminescent Ceramics : Fundamentals, Properties, Processing and Applications / Morteza Sasani Ghamsari and Hyung-Ho Park, editors.

Format:

Book

Contributor:

Sasani Ghamsari, Morteza, editor.

Park, Hyung-Ho, editor.

Series:

Elsevier Series in Advanced Ceramic Materials Series

Language:

English

Subjects (All):

Ceramics.

Luminophores.

Phosphors.

Local Subjects:

Luminophores.

Physical Description:

1 online resource (508 pages)

Edition:

First edition.

Place of Publication:

Amsterdam, Netherlands : Elsevier Ltd., [2025]

Summary:

Luminescent Ceramics: Fundamentals, Properties, Processing and Applications provides a detailed review of luminescent ceramic materials for lighting, dosimetry and security.The book's chapters cover oxide, nitride and fluoride phosphors, garnet transparent ceramics, oxynitride and BeO ceramics, doped MgAl2O4 ceramics for dosimetry and novel.

Contents:

Front Cover

Luminescent Ceramics

Copyright Page

Contents

List of contributors

I. Introduction to luminescent ceramics

1 The fundamentals of light-related phenomena in ceramic materials

1.1 Introduction

1.2 Characteristics of luminescence

1.2.1 Luminescence power

1.2.2 Luminescence spectrum

1.2.3 Luminescence polarization

1.2.4 Optical indicatrix

1.2.5 Energy and quantum yields

1.2.6 Anti-Stokes luminescence

1.2.7 Luminescence rise and decay

1.2.8 Thermoluminescence

1.2.9 Hot luminescence

1.3 Luminescence mechanisms

1.3.1 Luminescence based on excited state within the molecules

1.3.1.1 Luminescence in rare earth metal complexes

1.3.2 Luminescence in rare earth doped solids

1.3.3 Luminescence based on configurational coordinates

1.3.3.1 Classification of localized centers

1.3.4 Luminescence based on energy band formation in solids

1.4 Quantum aspect of luminescence

1.4.1 Electronic states in an ideal crystal

1.4.2 Lattice vibrations: phonons

1.4.3 Impurity levels and bands

References

II. Applications of luminescent ceramics

2 Oxide phosphors

2.1 Introduction

2.2 Oxide phosphors for white light emitting diodes

2.2.1 Phosphate phosphors

2.2.2 Aluminate phosphors

2.2.3 Silicate phosphors

2.2.4 Other phosphors

2.3 Oxide phosphors for plasma display panels (PDPs)

2.3.1 Red oxide phosphors

2.3.2 Green oxide phosphors

2.3.3 Blue oxide phosphors

2.4 Oxide phosphors for sensors

2.5 Oxide phosphors for magnetic resonance and fluorescence imaging

2.6 Oxide phosphors for solar cells

2.7 Oxide phosphors for plant cultivation

2.8 Conclusion

3 Fluoride phosphors

3.1 Introduction

3.2 Electronic energy-level states in Mn4+ and Cr3+ ions

3.3 Synthetic strategies

3.3.1 Chemical etching synthesis.

3.3.2 Cation exchange synthesis

3.3.3 Hydrothermal synthesis

3.3.4 Co-precipitation synthesis

3.4 Representative fluoride phosphors activated with Mn4+ or Cr3+ ions

3.4.1 K2SiF6:Mn4+

3.4.2 K3ScF6:Cr3+

3.5 Applications of fluoride phosphors in lighting, display, and imaging fields

3.5.1 Lighting

3.5.2 Displays

3.5.3 Imaging

3.6 Conclusion

Acknowledgments

4 BeO ceramics

4.1 Introduction

4.2 Production of beryllium oxide

4.2.1 Sol-gel synthesis of beryllium oxide

4.2.2 Precipitation synthesis of beryllium oxide

4.2.3 Heat treatments

4.3 Luminescence of beryllium oxide

4.3.1 Radioluminescence of beryllium oxide

4.3.2 Thermoluminescence of beryllium oxide

4.3.3 Optically stimulated luminescence of beryllium oxide

4.4 Dosimetric properties of beryllium oxide

4.5 Conclusions

5 Effect of different dopant elements on thermoluminescence properties MgAl2O4

5.1 Introduction

5.2 Luminescence

5.3 Crystal structure of MgAl2O4

5.4 MgO-Al2O3 phase diagram

5.5 Dosimeter properties

5.5.1 Two simple TL models

5.5.2 Dopant on MgAl2O4 TSL

5.6 Comparison of results and conclusion

6 Novel thermo-luminescent ceramics

6.1 Introduction to thermoluminescence materials

6.2 Theory of thermoluminescence

6.3 Thermoluminescence materials

6.4 Properties of thermo-luminescent ceramic

6.4.1 Bottom of form

6.5 Thermoluminescent analysis techniques

6.6 Synthesis and characterization of novel thermo-luminescent ceramic materials

6.6.1 Core-shell structures

6.6.2 Glass-ceramic phosphors

6.7 Challenges and future directions

6.7.1 Novel luminescent ceramics

6.7.2 Future trends in luminescent ceramics

6.8 Conclusion

7 Novel luminescent transparent ceramics for light emitting devices.

7.1 Introduction

7.2 Synthesis of transparent ceramics

7.3 Transparent ceramics for high power LED/LD

7.4 Transparent ceramic lasers

7.5 Glass ceramics for light emitting device applications

7.6 Persistent luminescence ceramics/glass ceramics for display

7.7 Transparent ceramics for scintillators

7.8 Conclusions

Further reading

8 Luminescent materials for anticounterfeiting inks and fingerprint imaging

8.1 Introduction

8.2 Luminescent nanoparticles for anticounterfeiting inks and latent fingerprints imaging

8.2.1 Ultraviolet-sensitive inks based on fluorescent nanoparticles

8.2.2 Fluorescent nanoparticles for latent fingerprints imaging

8.3 Lanthanide-based complexes for anticounterfeiting inks and latent fingerprints imaging

8.3.1 Luminescence properties

8.3.2 Anticounterfeiting applications and latent fingerprints imaging

8.4 Summary

9 Luminescent thermometers based on lanthanide

9.1 Introduction

9.2 Upconverting nanoparticles and downshifting nanoparticles based on Ln3+ for thermometry

9.2.1 Upconversion nanoparticles-thermometers

9.2.2 Downshifting nanoparticles-thermometers

9.3 Luminescence thermometry

9.3.1 Concept of luminescence thermometry based on lanthanides

9.3.2 Principles of temperature measurements

9.3.3 Performance of thermometers

9.3.4 Importance of core/shell structure on thermometric performances

9.4 Conclusion

10 Luminescent materials for textile

10.1 Introduction

10.2 Luminescence and photoluminescence

10.3 The existing luminescent materials: advantages and limitations

10.3.1 Classification of luminescent materials

10.3.2 Advantages and limitations of phosphors

10.4 Luminescent smart textile

10.5 Conclusion

11 Lanthanide-doped Y2O3 nanophosphors

11.1 Introduction.

11.2 Fundamentals of luminescence

11.2.1 Theories and principles

11.2.2 Electronic states and transitions

11.3 Lanthanide-doped yttria

11.3.1 Red &amp

red-orange colors

11.3.2 Yellow color

11.3.3 Green color

11.3.4 Blue color

11.3.5 Blue-far yellow color

11.4 Applications

11.5 Colloidal Ln3+-doped Y2O3

11.5.1 Colloidal Nd3+:Y2O3 nanoparticles

12 Nitride phosphors

12.1 Solid state lighting: a sustainable efficient and green technology

12.1.1 White-light-emitting diode for solid state lighting

12.1.2 Phosphors converted white light-emitting diodes

12.2 Nitride phosphors

12.2.1 Crystal site engineering

12.2.2 Energy transfer approach

12.3 Optical thermometry based on nitride phosphors

12.4 Other applications of nitride phosphors

12.5 Advantages and limitations

12.6 Conclusion

Acknowledgment

Index

Back Cover.

Notes:

Includes bibliographical references and index.

Description based on publisher supplied metadata and other sources.

Description based on print version record.

ISBN:

9780323914444

0323914446

9780323911375

0323911374

OCLC:

1478693640