Abstract

Series Preface. Preface. 1 Principles of Luminescence (Adrian H. Kitai). 1.1 Introduction. 1.2 Radiation Theory. 1.3 Simple Harmonic Radiator. 1.4 Quantum Description. 1.5 Selection Rules. 1.6 Einstein Coefficients. 1.7 Harmonic Perturbation. 1.8 Blackbody Radiation. 1.9 Dipole-Dipole Energy Transfer. 1.10 Energy Levels in Atoms. 1.11 Crystal Field Splitting. Acknowledgement. References. 2 Phosphor Quantum Dots (Debasis Bera, Lei Qian and Paul H. Holloway). 2.1 Introduction. 2.2 Nanostructured Materials. 2.3 Quantum Dots. 2.4 Relaxation Processes of Excitons. 2.5 Blinking Effect. 2.6 Surface Passivation. 2.7 Synthesis Processes. 2.8 Optical Properties and Applications. 2.9 Perspective. Acknowledgement. References. 3 Color Conversion Phosphors for LEDS (Jack Silver and Robert Withnall). 3.1 Introduction. 3.2 Disadvantages of using LEDs without Color Conversion Phosphors. 3.3 Phosphors for Converting the Color of Light Emitted by LEDs. 3.4 Survey of the Synthesis and Properties of some Currently Available Color Conversion Phosphors. 3.5 Multi-Phosphor pcLEDs. 3.6 Quantum Dots. 3.7 Conclusions. Acknowledgements. References. 4 Development of White OLED Technology for Application in Full-Color Displays and Solid-State Lighting (T. K. Hatwar and Jeff Spindler). 4.1 Introduction. 4.2 Generation of White Light. 4.3 White OLEDs for Display Applications. 4.4 White OLED Tandem Architecture. 4.5 White OLEDs Based on Triplets. 4.6 White OLEDs Based on Conjugated Polymers. 4.7 White OLEDs for Solid-State Lighting. 4.8 Advanced Manufacturing of Large-Area Coatings. 4.9 Future Outlook. Acknowledgements. References. 5 Polymer Light-Emitting Electrochemical Cells (Jun Gao). 5.1 Introduction. 5.2 LEC Operating Mechanism and Device Characteristics. 5.3 LEC Materials. 5.4 Frozen-Junction LECs. 5.5 Planar LECs. 5.6 Conclusions and Outlook. References. 6 LED Materials and Devices (Tsunemasa Taguchi). 6.1 Introduction. 6.2 LED Structures and Effi ciencies. 6.3 Typical LEDs and Features. 6.4 Generation of White Light. 6.5 Devices and Applications. 6.6 Future Prospects. 6.7 Conclusions. References. 7 Thin Film Electroluminescence (Adrian H. Kitai). 7.1 Introduction. 7.2 Background of EL. 7.2.4 Sphere-supported thin film EL. 7.3 Theory of Operation. 7.4 Electroluminescent Phosphors. 7.5 Device Structures. 7.6 EL Phosphor Thin Film Growth. 7.7 Full-Color Electroluminescence. 7.8 Conclusions. References. 8 AC Powder Electroluminescence (Feng Chen and Yingwei Xiang). 8.1 Background. 8.2 Structure and Materials of AC Powder EL Devices. 6 LED Materials and Devices (Tsunemasa Taguchi). 6.1 Introduction. 6.2 LED Structures and Effi ciencies. 6.3 Typical LEDs and Features. 6.4 Generation of White Light. 6.5 Devices and Applications. 6.6 Future Prospects. 6.7 Conclusions. References. 7 Thin Film Electroluminescence (Adrian H. Kitai). 7.1 Introduction. 7.2 Background of EL. 7.3 Theory of Operation. 7.4 Electroluminescent Phosphors. 7.5 Device Structures. 7.6 EL Phosphor Thin Film Growth. 7.7 Full-Color Electroluminescence. 7.8 Conclusions. References. 8 AC Powder Electroluminescence (Feng Chen and Yingwei Xiang). 8.1 Background. 8.2 Structure and Materials of AC Powder EL Devices. 8.3 The Mechanism of Light Emission for AC ZnS-Powder-EL Device. 8.4 EL Characteristics of AC Powder EL Materials. 8.5 Preparation of Powder EL materials. 8.6 Limitations of AC Powder EL Devices. 8.7 Applications of ACPEL. References. Index.

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