Nitride Semiconductor Light-Emitting Diodes (LEDs)
Materials, Technologies and Applications

A practical look at the fabrication, performance, and applications of nitride-based LEDs for physicists, materials scientists, and engineers in industry

Jian-Jang Huang (Author), Hao-Chung Kuo (Author), Shyh-Chiang Shen (Author)

9780081014066

Paperback / softback, published 19 August 2016

650 pages
23.3 x 15.6 x 4 cm, 0.93 kg

The development of nitride-based light-emitting diodes (LEDs) has led to advancements in high-brightness LED technology for solid-state lighting, handheld electronics, and advanced bioengineering applications. Nitride Semiconductor Light-Emitting Diodes (LEDs) reviews the fabrication, performance, and applications of this technology that encompass the state-of-the-art material and device development, and practical nitride-based LED design considerations.

• Contributor contact details
• Woodhead Publishing Series in Electronic and Optical Materials
• Dedication
• Preface
• Part I: Materials and fabrication
  • 1: Molecular beam epitaxy (MBE) growth of nitride semiconductors
    • Abstract
    • 1.1 Introduction
    • 1.2 Molecular beam epitaxial (MBE) growth techniques
    • 1.3 Plasma-assisted MBE (PAMBE) growth of nitride epilayers and quantum structures
    • 1.4 Nitride nanocolumn (NC) materials
    • 1.5 Nitride nanostructures based on NCs
    • 1.6 Conclusion
  • 2: Modern metal-organic chemical vapor deposition (MOCVD) reactors and growing nitride-based materials
    • Abstract
    • 2.1 Introduction
    • 2.2 MOCVD systems
    • 2.3 Planetary reactors
    • 2.4 Close-coupled showerhead (CCS) reactors
    • 2.5 In situ monitoring systems and growing nitride-based materials
    • 2.6 Acknowledgements
  • 3: Gallium nitride (GaN) on sapphire substrates for visible LEDs
    • Abstract
    • 3.1 Introduction
    • 3.2 Sapphire substrates
    • 3.3 Strained heteroepitaxial growth on sapphire substrates
    • 3.4 Epitaxial overgrowth of GaN on sapphire substrates
    • 3.5 GaN growth on non-polar and semi-polar surfaces
    • 3.6 Future trends
  • 4: Gallium nitride (GaN) on silicon substrates for LEDs
    • Abstract
    • 4.1 Introduction
    • 4.2 An overview of gallium nitride (GaN) on silicon substrates
    • 4.3 Silicon overview
    • 4.4 Challenges for the growth of GaN on silicon substrates
    • 4.5 Buffer-layer strategies
    • 4.6 Device technologies
    • 4.7 Conclusion
  • 5: Phosphors for white LEDs
    • Abstract
    • 5.1 Introduction
    • 5.2 Optical transitions of Ce^3 + and Eu^2 +
    • 5.3 Chemical composition of representative nitride and oxynitride phosphors
    • 5.4 Compounds activated by Eu^2 +
    • 5.5 Compounds activated by Ce^3 +
    • 5.6 Features of the crystal structure of nitride and oxynitride phosphors
    • 5.7 Features of optical transitions of nitride and oxynitride phosphors
    • 5.8 Conclusion and future trends
    • 5.9 Acknowledgements
  • 6: Fabrication of nitride LEDs
    • Abstract
    • 6.1 Introduction
    • 6.2 GaN-based flip-chip LEDs and flip-chip technology
    • 6.3 GaN FCLEDs with textured micro-pillar arrays
    • 6.4 GaN FCLEDs with a geometric sapphire shaping structure
    • 6.5 GaN thin-film photonic crystal (PC) LEDs
    • 6.6 PC nano-structures and PC LEDs
    • 6.7 Light emission characteristics of GaN PC TFLEDs
    • 6.8 Conclusion
  • 7: Nanostructured LEDs
    • Abstract
    • 7.1 Introduction
    • 7.2 General mechanisms for growth of gallium nitride (GaN) related materials
    • 7.3 General characterization method
    • 7.4 Top-down technique for nanostructured LEDs
    • 7.5 Bottom-up technique for GaN nanopillar substrates prepared by molecular beam epitaxy
    • 7.6 Conclusion
  • 8: Nonpolar and semipolar LEDs
    • Abstract
    • 8.1 Motivation: limitations of conventional c-plane LEDs
    • 8.2 Introduction to selected nonpolar and semipolar planes
    • 8.3 Challenges in nonpolar and semipolar epitaxial growth
    • 8.4 Light extraction for nonpolar and semipolar LEDs
• Part II: Performance of nitride LEDs
  • 9: Efficiency droop in gallium indium nitride (GaInN)/gallium nitride (GaN) LEDs
    • Abstract
    • 9.1 Introduction
    • 9.2 Recombination models in LEDs
    • 9.3 Thermal roll-over in gallium indium nitride (GaInN) LEDs
    • 9.4 Auger recombination
    • 9.5 High-level injection and the asymmetry of carrier concentration and mobility
    • 9.6 Non-capture of carriers
    • 9.7 Polarization fields
    • 9.8 Carrier delocalization
    • 9.9 Discussion and comparison of droop mechanisms
    • 9.10 Methods for overcoming droop
  • 10: Photonic crystal nitride LEDs
    • Abstract
    • 10.1 Introduction
    • 10.2 Photonic crystal (PC) technology
    • 10.3 Improving LED extraction efficiency through PC surface patterning
    • 10.4 PC-enhanced light extraction in P-side up LEDs
    • 10.5 Modelling PC-LEDs
    • 10.6 P-side up PC-LED performance
    • 10.7 PC-enhanced light extraction in N-side up LEDs
    • 10.8 Summary
    • 10.9 Conclusions
  • 11: Surface plasmon enhanced LEDs
    • Abstract
    • 11.1 Introduction
    • 11.2 Mechanism for plasmon-coupled emission
    • 11.3 Fabrication of plasmon-coupled nanostructures
    • 11.4 Performance and outlook
    • 11.5 Acknowledgements
  • 12: Nitride LEDs based on quantum wells and quantum dots
    • Abstract
    • 12.1 Light-emitting diodes (LEDS)
    • 12.2 Polarization effects in III-nitride LEDs
    • 12.3 Current status of III-nitride LEDs
    • 12.4 Modern LED designs and enhancements
  • 13: Color tunable LEDs
    • Abstract
    • 13.1 Introduction
    • 13.2 Initial idea for stacked LEDs
    • 13.3 Second-generation LED stack with inclined sidewalls
    • 13.4 Third-generation tightly integrated chip-stacking approach
    • 13.5 Group-addressable pixelated micro-LED arrays
    • 13.6 Conclusions
  • 14: Reliability of nitride LEDs
    • Abstract
    • 14.1 Introduction
    • 14.2 Reliability testing of nitride LEDs
    • 14.3 Evaluation of LED degradation
    • 14.4 Degradation mechanisms
    • 14.5 Conclusion
  • 15: Chip packaging: encapsulation of nitride LEDs
    • Abstract
    • 15.1 Functions of LED chip packaging
    • 15.2 Basic structure of LED packaging modules
    • 15.3 Processes used in LED packaging
    • 15.4 Optical effects of gold wire bonding
    • 15.5 Optical effects of phosphor coating
    • 15.6 Optical effects of freeform lenses
    • 15.7 Thermal design and processing of LED packaging
    • 15.8 Conclusion
• Part III: Applications of nitride LEDs
  • 16: White LEDs for lighting applications: the role of standards
    • Abstract
    • 16.1 General lighting applications
    • 16.2 LED terminology
    • 16.3 Copying traditional lamps?
    • 16.4 Freedom of choice
    • 16.5 Current and future trends
  • 17: Ultraviolet LEDs
    • Abstract
    • 17.1 Research background of deep ultraviolet (DUV) LEDs
    • 17.2 Growth of low threading dislocation density (TDD) AlN layers on sapphire
    • 17.3 Marked increases in internal quantum efficiency (IQE)
    • 17.4 Aluminum gallium nitride (AlGaN)-based DUV-LEDs fabricated on high-quality aluminum nitride (AlN)
    • 17.5 Increase in electron injection efficiency (EIE) and light extraction efficiency (LEE)
    • 17.6 Conclusions and future trends
  • 18: Infrared emitters made from III-nitride semiconductors
    • Abstract
    • 18.1 Introduction
    • 18.2 High indium (In) content alloys for infrared emitters
    • 18.3 Rare-earth (RE) doped gallium nitride (GaN) emitters
    • 18.4 III-nitride materials for intersubband (ISB) optoelectronics
    • 18.5 ISB devices
    • 18.6 Conclusions
    • 18.7 Acknowledgements
  • 19: LEDs for liquid crystal display (LCD) backlighting
    • Abstract
    • 19.1 Introduction
    • 19.2 Types of LED LCD backlighting units (BLUs)
    • 19.3 Technical considerations for optical films and plates
    • 19.4 Requirements for LCD BLUs
    • 19.5 Advantages and history of LED BLUs
    • 19.6 Market trends and technological developments
    • 19.7 Optical design
  • 20: LEDs in automotive lighting
    • Abstract
    • 20.1 Introduction
    • 20.2 Forward lighting
    • 20.3 Signal lighting
    • 20.4 Human factor issues with LEDs
    • 20.5 Energy and environmental issues
    • 20.6 Future trends
    • 20.7 Sources of further information and advice
    • 20.8 Acknowledgments
• Index

Subject Areas: Laser technology & holography [TTBL], Applied optics [TTB], Electrical engineering [THR], Materials science [TGM]