The Global Market for MicroLED Displays 2024-2034

PUBLISHED: December 7, 2023

PAGES: 335 Pages, 97 Tables, 128 Figures

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MicroLED is a self-emitting display consisting of arrays of microscopic LEDs each forming a pixel. MicroLED commercial activity is picking up considerably. Apple has plans to invest>$2 billion establishing smartwatch display production with 8" MicroLED chip fab at ams-Osram. Epistar and AUO are building a 6" MicroLED foundry leveraging PlayNitride technology. AUO will also begin production of a smart watch display 1.39" in Q4 23. Jade Bird Display has commenced it's production line in Hefei, with the total capacity of 120 million 0.13" MicroLED panels. Several other companies have also set up pilot lines for production. and Samsung is planning to increase manufacturing of microLED TV in 2023. Companies including Raysolve, Hon Hai (Foxconn) and Mojo Vision have recently announced breakthroughs using quantum dots in micro-LED displays.

“The Global Market for MicroLED Displays 2024-2034” is an in-depth 330+ page market report providing a comprehensive analysis of emerging Micro-LED display technologies and markets. It evaluates the current status and future outlook for these next-generation LED displays across applications in consumer electronics, automotive, augmented reality, transparent displays, digital signage, and more.

The report profiles over 80 leading companies developing MicroLED products including display manufacturers, LED chip/emitter companies, equipment suppliers and start-ups. It assesses their technology capabilities, product roadmaps, partnerships, and competitive positioning. Detailed technical analysis is provided on MicroLED manufacturing processes such as epitaxial growth, mass transfer techniques, assembly and interconnect technologies. The report compares performance metrics of Micro-LED displays including benefits/drawbacks versus LCD and OLED displays.

In-depth market analysis is provided on adoption trends, drivers and challenges across key industry verticals. Quantitative 10+ year market forecasts are included for MicroLED display shipments and revenues globally and segmented by product categories, regions and application markets. Overall this report is the most comprehensive source of strategic analysis on the MicroLED display technologies and associated market opportunities through 2034. It is a vital reference for display industry participants, investors, electronics OEMs, and technology companies seeking an in-depth understanding of these emerging displays.

Report contents include:

Technology Introductions to MicroLED Displays
Comparative Analysis of Mini-LED vs Micro-LED
Manufacturing Processes for MicroLED Displays
Chip Fabrication, Epitaxial Growth, Wafer Production
Assembly, Hybrid Integration, Mass Transfer Techniques
Defect Management, Repair and Optimization
Colour Conversion Technologies for MicroLED
Analysis of MicroLED Performance Metrics
Assessment of Benefits and Drawbacks vs LCD and OLED
Emerging Innovations: Flexible, Transparent, 3D Displays
Adoption Roadmaps and Market Opportunities by Application:
- Consumer Electronics, Automotive Displays, Signage
- AR/VR Devices, Transparent Displays, Lighting, Medical
Supply Chain Ecosystems for MicroLED Displays
Company Profiles of 80+ MicroLED Developers. Companies profiled include AUO, eLux, Innolux, Jade Bird Display, LG Display, Mikro Mesa, Mojo Vision, PlayNitride, Porotech, Raysolve Technology, Q-Pixel, Samsung Electronics, Sitan Semiconductor International Co. Ltd., Tianma, and Sony.
10-Year Market Forecasts for MicroLED Display Shipments and Revenues
Analysis of Market Drivers, Trends, and Technology Challenges
Regional Markets: North America, Asia-Pacific, Europe, ROW

1. REPORT AIMS AND OBJECTIVES

2. EXECUTIVE SUMMARY

2.1. The MiniLED market
2.2. The MicroLED market
2.3. The global display market
- 2.3.1. OLEDs
- 2.3.2. Quantum dots
- 2.3.3. Display technologies assessment
2.4. Benefits of MicroLEDs
2.5. Additive manufacturing for microLED micro-displays
2.6. MicroLEDs applications
2.7. Market and technology challenges
2.8. Industry developments 2020-2023
2.9. Recent microLED display innovations
2.10. Market activity in China
2.11. Global shipment forecasts for MicroLEDs to 2034
- 2.11.1. Units
- 2.11.2. Revenues

3. TECHNOLOGY INTRODUCTION

3.1. What are MicroLEDs?
3.2. MiniLED (mLED) vs MicroLED (µLED)
- 3.2.1. Display configurations
- 3.2.2. Development
  - 3.2.2.1. Sony
- 3.2.3. Types
- 3.2.4. Production
  - 3.2.4.1. Integration
  - 3.2.4.2. Transfer technologies
- 3.2.5. Comparison to LCD, OLED AND QD
- 3.2.6. MicroLED display specifications
- 3.2.7. Advantages
  - 3.2.7.1. Transparency
  - 3.2.7.2. Borderless
  - 3.2.7.3. Flexibility
- 3.2.8. Tiled microLED displays
- 3.2.9. Costs
  - 3.2.9.1. Relationship between microLED cost and die size

4. MANUFACTURING

4.1. Epitaxy and Chip Processing
- 4.1.1. Materials
- 4.1.2. Substrates
  - 4.1.2.1. Green gap
- 4.1.3. Wafer patterning
- 4.1.4. Metal organic chemical vapor deposition (MOCVD)
- 4.1.5. Epitaxial growth requirement
- 4.1.6. Molecular beam epitaxy (MBE)
- 4.1.7. Uniformity
4.2. Chip manufacturing
- 4.2.1. RGB microLED designs
- 4.2.2. Epi-film transfer
4.3. MicroLED Performances
- 4.3.1. Relationship between external quantum efficiency (EQE) and current density
- 4.3.2. Stability and thermal management
- 4.3.3. Size dependency
- 4.3.4. Surface recombination of carriers
- 4.3.5. Developing efficient high-performance RGB microLEDs
4.4. Transfer, Assembly and Integration Technologies
- 4.4.1. Monolithic integration
  - 4.4.1.1. Overview
  - 4.4.1.2. Companies
- 4.4.2. Heterogeneous Wafers
  - 4.4.2.1. Array integration
  - 4.4.2.2. Wafer bonding
  - 4.4.2.3. Hybridization integration
  - 4.4.2.4. Companies
- 4.4.3. Monolithic microLED arrays
- 4.4.4. GaN on Silicon
  - 4.4.4.1. Overview
  - 4.4.4.2. Types
    - 4.4.4.2.1. GaN on sapphire
  - 4.4.4.3. Challenges
  - 4.4.4.4. Companies
- 4.4.5. Mass transfer
  - 4.4.5.1. Chiplet Mass Transfer
  - 4.4.5.2. Elastomer Stamp Transfer (Fine pick and place)
    - 4.4.5.2.1. Overview
    - 4.4.5.2.2. Controlling kinetic adhesion forces
    - 4.4.5.2.3. Pixel pitch
    - 4.4.5.2.4. Micro-transfer printing
    - 4.4.5.2.5. Capillary-assisted transfer printing
    - 4.4.5.2.6. Electrostatic array
    - 4.4.5.2.7. Companies
  - 4.4.5.3. Roll-to-Roll or Roll-to-Panel Imprinting
  - 4.4.5.4. Laser enabled transfer
    - 4.4.5.4.1. Overview
      - 4.4.5.4.1.1. Selective transfer by selective bonding-debonding
    - 4.4.5.4.2. Companies
  - 4.4.5.5. Electrostatic Transfer
  - 4.4.5.6. Micro-transfer
    - 4.4.5.6.1. Overview
    - 4.4.5.6.2. Micro-Pick-and-Place Transfer
    - 4.4.5.6.3. Photo-Polymer Mass Transfer
    - 4.4.5.6.4. Companies
  - 4.4.5.7. Micro vacuum-based transfer
  - 4.4.5.8. Adhesive Stamp
  - 4.4.5.9. Self-Assembly
    - 4.4.5.9.1. Overview
    - 4.4.5.9.2. Fluidically Self-Assembled (FSA) technology
    - 4.4.5.9.3. Magnetically-assisted assembly
    - 4.4.5.9.4. Photoelectrochemically driven fluidic-assembly
    - 4.4.5.9.5. Electrophoretic fluidic-assembly
    - 4.4.5.9.6. Surface energy fluidic-assembly
    - 4.4.5.9.7. Shape-based self-assembly
    - 4.4.5.9.8. Companies
  - 4.4.5.10. All-In-One Transfer
    - 4.4.5.10.1. Overview
    - 4.4.5.10.2. Heterogeneous Wafers in All-in-One Integration
      - 4.4.5.10.2.1. Optoelectronic Array Integration
      - 4.4.5.10.2.2. Wafer Bonding Process and Hybridization
    - 4.4.5.10.3. Companies
- 4.4.6. Nanowires
  - 4.4.6.1. Overview
    - 4.4.6.1.1. Nanowire Growth on Silicon
    - 4.4.6.1.2. Native EL RGB nanowires
    - 4.4.6.1.3. 3D Integration
- 4.4.7. Bonding and interconnection
  - 4.4.7.1. Overview
  - 4.4.7.2. Types of bonding
  - 4.4.7.3. Microtube Interconnections

5. DEFECT MANAGEMENT

5.1. Overview
5.2. Defect types
5.3. Redundancy techniques
5.4. Repair
- 5.4.1. Techniques
- 5.4.2. Laser micro trimming

6. COLOUR CONVERSION

6.1. Comparison of technologies
6.2. Full colour conversion
6.3. UV LED
6.4. Colour filters
6.5. Stacked RGB MicroLEDs
- 6.5.1. Companies
6.6. Three panel microLED projectors
6.7. Phosphor Colour Conversion
- 6.7.1. Overview
  - 6.7.1.1. Red-emitting phosphor materials
  - 6.7.1.2. Thermal stability
  - 6.7.1.3. Narrow-band green phosphors
  - 6.7.1.4. High performance organic phosphors
- 6.7.2. Challenges
- 6.7.3. Companies
6.8. Quantum dots colour conversion
- 6.8.1. Mode of operation
- 6.8.2. Cadmium QDs
- 6.8.3. Cadmium-free QDs
- 6.8.4. Perovskite quantum dots
- 6.8.5. Graphene quantum dots
- 6.8.6. Phosphors and quantum dots
- 6.8.7. Quantum dots in microLED displays
  - 6.8.7.1. Technology overview
  - 6.8.7.2. QD-based display types
  - 6.8.7.3. Quantum dot colour conversion (QDCC) technology for microLEDs
  - 6.8.7.4. Efficiency drop and red shift in quantum dot emission for displays
  - 6.8.7.5. High blue absorptive quantum dot materials for display
  - 6.8.7.6. QD display pixel patterning techniques
    - 6.8.7.6.1. Inkjet printing
    - 6.8.7.6.2. Photoresists
    - 6.8.7.6.3. Aerosol Jet Printing
- 6.8.8. Challenges
- 6.8.9. Companies
6.9. Quantum wells
6.10. Improving image quality

7. LIGHT MANAGEMENT

7.1. Overview
7.2. Light capture methods
7.3. Micro-catadioptric optical array
7.4. Additive manufacturing (AM) for engineered directional emission profiles

8. BACKPLANES AND DRIVING

8.1. Overview
8.2. Technologies and materials
- 8.2.1. TFT materials
- 8.2.2. OLED Pixel Driving
- 8.2.3. TFT Backplane
- 8.2.4. Passive and active matrix addressing
  - 8.2.4.1. Passive Matrix Addressing
  - 8.2.4.2. Passive Driving Structure
  - 8.2.4.3. Active Matrix Addressing
  - 8.2.4.4. Pulse width modulation (PWM)
  - 8.2.4.5. Driving voltage considerations for microLEDs
- 8.2.5. RGB Driving Schemes for MicroLED Displays
- 8.2.6. Active Matrix MicroLED Displays with LTPS Backplanes

9. CONSUMER ELECTRONIC DISPLAYS

9.1. Market map
9.2. Market adoption roadmap
9.3. Large flat panel displays and TVs
- 9.3.1. Samsung
  - 9.3.1.1. Wall display
  - 9.3.1.2. Neo QLED TV range
  - 9.3.1.3. MicroLED CX TV line-up
- 9.3.2. LG
  - 9.3.2.1. MAGNIT MicroLED TV
- 9.3.3. TCL CSOT
9.4. Smartwatches and wearables
- 9.4.1. Apple's planned microLED smartwatch
- 9.4.2. Samsung
9.5. Smartphones
9.6. Laptops, monitors and tablets
9.7. Foldable and stretchable displays
- 9.7.1. The global foldable display market
- 9.7.2. Applications
  - 9.7.2.1. Foldable TVs
  - 9.7.2.2. Stretchable 12" microLED touch displays
  - 9.7.2.3. Product developers

10. BIOTECH AND MEDICAL

10.1. The global medical display market
10.2. Applications
- 10.2.1. Implantable Devices
- 10.2.2. Lab-on-a-Chip
- 10.2.3. Endoscopy
- 10.2.4. Surgical Displays
- 10.2.5. Phototherapy
- 10.2.6. Biosensing
- 10.2.7. Brain Machine Interfaces
10.3. Product developers

11. AUTOMOTIVE

11.1. Global automotive displays market
11.2. Applications
- 11.2.1. Cabin Displays
- 11.2.2. Head-up displays (HUD)
- 11.2.3. Exterior Signaling and Lighting
11.3. Product developers

12. VIRTUAL REALITY (VR), AUGMENTED REALITY (AR) AND MIXED REALITY (MR)

12.1. Global market for virtual reality (VR), augmented reality (AR), and mixed reality (MR)
12.2. Applications
- 12.2.1. AR/VR Smart glasses and head-mounted displays (HMDs)
- 12.2.2. MicroLED contact lenses
12.3. Products developers

13. TRANSPARENT DISPLAYS

13.1. Global transparent displays market
13.2. Applications
- 13.2.1. Smart Windows
- 13.2.2. Display Glass Overlays
13.3. Product developers

14. SUPPLY CHAINS

15. COMPANY PROFILES (83 company profiles)

16. REFERENCES

List of Tables

Table 1. Announced MicroLED fabs
Table 2. Summary of display technologies
Table 3. Advantages of AM microLED micro-displays
Table 4. MicroLED applications
Table 5. Market and technology challenges for microLEDs
Table 6. MicroLED industry developments 2020-2023
Table 7. MicroLED product announcements at CES 2021
Table 8. MicroLED product announcements at CES 2022 and Display Week 2022
Table 9. MicroLED product announcements at CES 2023 and Display Week 2023
Table 10. MicroLED activity in China
Table 11. Global MicroLED display market (thousands of units) 2020-2034
Table 12. LED size definitions
Table 13. Comparison between miniLED and microLED
Table 14. Comparison to conventional LEDs
Table 15. Types of MicroLED
Table 16. Summary of monolithic integration, monolithic hybrid integration (flip-chip/wafer bonding), and mass transfer technologies
Table 17. Summary of different mass transfer technologies
Table 18. MicroLED Comparison to LCD, OLED and QD
Table 19. Schematic comparison to LCD and OLED
Table 20. Commercially available MicroLED products and specifications
Table 21. Comparison of MicroLED with other display technologies
Table 22. MicroLED-based display advantages and disadvantages
Table 23. Materials for commercial LED chips
Table 24. Bandgap vs lattice constant for common III-V semiconductors used in LEDs
Table 25. Advantages and disadvantages of MOCVD
Table 26. Typical RGB microLED designs
Table 27. Size dependence of key parameters in microLEDs
Table 28. Transfer, assembly and integration technologies
Table 29. Companies utilizing monolithic integration for MicroLEDs
Table 30. Advantages and disadvantages of heterogeneous wafers
Table 31. Key players in heterogeneous wafers
Table 32. Fabricating monolithic micro-displays
Table 33. GaN-on-Si applications
Table 34. Different epitaxial growth methods for GaN-on-Silicon
Table 35. Comparison of GaN growth on sapphire vs silicon substrates
Table 36. Cost comparison of sapphire versus silicon substrates for GaN epitaxy
Table 37. Challenges of GaN-on-Silicon epitaxy and mitigation strategies
Table 38. Companies utilizing GaN microLEDs on silicon
Table 39. Mass transfer methods, by company
Table 40. Comparison of various mass transfer technologies
Table 41. Factors affecting transfer yield for microLED mass assembly
Table 42. Advantages and disadvantages of Elastomeric stamp for microLED mass transfer
Table 43. Companies utilizing elastomeric stamp transfer
Table 44. Laser beam requirement
Table 45. Companies utilizing laser-enabled transfer technology
Table 46. Companies developing micro-transfer printing technologies
Table 47. Types of self-assembly technologies
Table 48. Companies utilizing self-assembly
Table 49. Advantages and disadvantages of all-in-one CMOS driving technique
Table 50. Companies utilizing All-in-one transfer
Table 51. Comparison between 2D and 3D microLEDs
Table 52. Classification of key microLED bonding and interconnection techniques
Table 53. Types of bonding
Table 54. Strategies for full colour realization
Table 55. Comparison of colour conversion technologies for microLED displays
Table 56. Companies developing stacked RGB microLEDs
Table 57. Phosphor materials used for LED colour conversion
Table 58. Requirements for phosphors in LEDs
Table 59. Standard and emerging red-emitting phosphors
Table 60. Challenges with phosphor colour conversion
Table 61. Companies developing phosphors for MicroLEDs
Table 62. Comparative properties of conventional QDs and Perovskite QDs
Table 63. Properties of perovskite QLEDs comparative to OLED and QLED
Table 64. Perovskite-based QD producers
Table 65. Comparison between carbon quantum dots and graphene quantum dots
Table 66. Comparison of graphene QDs and semiconductor QDs
Table 67. Graphene quantum dots producers
Table 68. QDs vs phosphors
Table 69. QD-based display types
Table 70. Quantum dot (QD) patterning techniques
Table 71. Pros and cons of ink-jet printing for manufacturing displays
Table 72. Challenges with QD colour conversion
Table 73. Companies utilizing quantum dots in MicroLEDs
Table 74. Methods to capture light output
Table 75. Backplane and driving options for MicroLED displays
Table 76. Comparison between PM and AM addressing
Table 77. PAM vs PWM
Table 78. . Driving vs. EQE
Table 79. Comparison of LED TV technologies
Table 80. Samsung Neo QLED TV range
Table 81. LG mini QNED range
Table 82. Flexible, stretchable and foldable MicroLED products
Table 83. Medical display MicroLED products
Table 84. Automotive display & backlight architectures
Table 85. Applications of MicroLED in automotive
Table 86. Automotive display MicroLED products
Table 87. Comparison of AR Display Light Engines
Table 88. MicroLED based smart glass products
Table 89. MicroLED transparent displays
Table 90. Companies developing MicroLED transparent displays
Table 91. MicroLED supply chain
Table 93. LG mini QNED range
Table 94. Samsung Neo QLED TV range
Table 95. San'an Mini and MicroLED Production annual target
Table 96. NPQDTM vs Traditional QD based MicroLEDs
Table 97. TCL MiniLED product range

List of Figures

Figure 1. Blue GaN MicroLED arrays with 3um pixel pitch use polychromatic quantum dot integration to achieve full colour AR displays
Figure 2: QLED TV from Samsung
Figure 3. QD display products
Figure 4. The progress of display technology, from LCD to MicroLED
Figure 5. Head-up displays (HUD)
Figure 6. Public advertising displays
Figure 7. Wearable biomedical devices
Figure 8. Pico-projectors
Figure 9. Mojo Vision's 300-mm GaN-on-silicon blue LED wafer for microLED displays
Figure 10. Global MicroLED display market (thousands of units) 2020-2034
Figure 11. Global MicroLED display market 2020-2034, by market (Million USD)
Figure 12. MicroLED display panel structure
Figure 13. Display system configurations
Figure 14. MicroLED schematic
Figure 15. Pixels per inch roadmap of µ-LED displays from 2007 to 2019
Figure 16. Mass transfer for µLED chips
Figure 17. Schematic diagram of mass transfer technologies
Figure 18. Lextar 10.6 inch transparent MicroLED display
Figure 19. Transition to borderless design
Figure 20. Process for LED Manufacturing
Figure 21. Main application scenarios of microLED display and their characteristic display area and pixel density
Figure 22. Conventional process used to fabricate microLED microdisplay devices
Figure 23. Process flow of Silicon Display of Sharp
Figure 24. JDB monolithic hybrid integration microLED chip fabrication process
Figure 25. Monolithic microLED array
Figure 26. Schematics of a elastomer stamping, b electrostatic/electromagnetic transfer, c laser-assisted transfer and d fluid self-assembly
Figure 27. Transfer process flow
Figure 28. XCeleprint Automated micro-transfer printing machinery
Figure 29. Schematics of Roll-based mass transfer
Figure 30. Schematic of laser-induced forward transfer technology
Figure 31. Schematic of fluid self-assembly technology
Figure 32. Fabrication of microLED chip array
Figure 33. Schematic of colour conversion technology
Figure 34. Process flow of a full-colour micro display
Figure 35. GE inkjet-printed red phosphors
Figure 36. Toray's organic colour conversion film
Figure 37. Quantum dot schematic
Figure 38. Quantum dot size and colour
Figure 39. (a) Emission colour and wavelength of QDs corresponding to their sizes (b) InP QDs; (c) InP/ZnSe/ZnS core-shell QDs
Figure 40. A pQLED device structure
Figure 41. Perovskite quantum dots under UV light
Figure 42. Market map for MicroLED displays
Figure 43. Market adoption roadmap for microLED displays
Figure 44. Samsung Wall display system
Figure 45. Samsung Neo QLED 8K
Figure 46. Samsung Electronics 89-inch microLED TV
Figure 47. MAGNIT MicroLED TV
Figure 48. MicroLED wearable display prototype
Figure 49. APHAEA Watch
Figure 50. AUO's 13.5-inch transparent RGB microLED display
Figure 51. AU Optonics Flexible MicroLED Display
Figure 52. Schematic of the TALT technique for wafer-level MicroLED transferring
Figure 53. 55" flexible AM panel
Figure 54. Foldable 4K C SEED M1
Figure 55. Stretchable 12" microLED touch displays
Figure 56. MicroLEDs for medical applications
Figure 57. 2023 Cadillac Lyriq EV incorporating miniLED display
Figure 58. MicroLED automotive display
Figure 59. Issues in current commercial automotive HUD
Figure 60. Rear lamp utilizing flexible MicroLEDs
Figure 61. LAWK ONE
Figure 62. JioGlass
Figure 63. Mojo Vision smart contact lens with an embedded MicroLED display
Figure 64. Cellid AR glasses, Exploded version
Figure 65. Air Glass
Figure 66. Panasonic MeganeX
Figure 67. Thunderbird Smart Glasses Pioneer Edition
Figure 68. RayNeo X2
Figure 69. tooz technologies smart glasses
Figure 70. Vuzix MicroLED micro display Smart Glasses
Figure 71. Leopard demo glasses by WaveOptics
Figure 72. Different transparent displays and transmittance limitations
Figure 73. 7.56" high transparency & frameless MicroLED display
Figure 74. 17.3-inch transparent microLED AI display in a Taiwan Ferry
Figure 75. WireLED in 12" Silicon Wafer
Figure 76. Typical GaN-on-Si LED structure
Figure 77. 300 mm GaN-on-silicon epiwafer
Figure 78. MicroLED chiplet architecture
Figure 79. Concept Apple Vr Ar Mixed Reality Headset
Figure 80. 1.39-inch full-circle MicroLED display
Figure 81. 9.4" flexible MicroLED display
Figure 82. BOE MiniLED display TV
Figure 83. BOE MiniLED automotive display
Figure 84. Image obtained on a blue active-matrix WVGA (wide video graphics array) micro display
Figure 85. Fabrication of the 10-µm pixel pitch LED array on sapphire
Figure 86. A 200-mm wafer with CMOS active matrices for GaN 873 x 500-pixel micro display at 10-µm pitch
Figure 87. IntelliPix™ design for 0.26" 1080p MicroLED display
Figure 88. C Seed 165-inch M1 MicroLED TV
Figure 89. N1 folding MicroLED TV
Figure 90. C Seed outdoor TV
Figure 91. Focally Universe AR glasses
Figure 92. Flexible MicroLED
Figure 93. Jade Bird Display micro displays
Figure 94. JBD's 0.13-inch panel
Figure 95. 0.22" Monolithic full colour MicroLED panel and inset shows a conceptual monolithic polychrome projector with a waveguide
Figure 96. Prototype MicroLED display
Figure 97. APHAEA MicroLED watch
Figure 98. KONKA 59" tiled microLED TV prototype screen
Figure 99. Lextar 2021 microLED and mini LED products
Figure 100. LSAB009 MicroLED display
Figure 101. LG MAGNIT 4K 136-inch TV
Figure 102. 12" 100 PPI full-colour stretchable microLED display
Figure 103. Schematic of Micro Nitride chip architecture
Figure 104. Nationstar Mini LED IMD Package P0.5mm
Figure 105. 9.4" flexible MicroLED display
Figure 106. 7.56-inch transparent MicroLED display
Figure 107. PixeLED Matrix Modular MicroLED Display in 132-inch
Figure 108. Dashboard - 11.6-inch 24:9 Automotive MicroLED Display
Figure 109. Center Console - 9.38-inch Transparent MicroLED Display
Figure 110. 48 x 36 Passive Matrix MicroLED display
Figure 111. MicroLED micro display based on a native red InGaN LED
Figure 112. MicroLED stretchable display
Figure 113. The Wall
Figure 114. Samsung Neo QLED 8K
Figure 115. NPQD™ Technology for MicroLEDs
Figure 116. Wicop technology
Figure 117. B-Series and C-Series displays
Figure 118. A micro-display with a stacked-RGB pixel array, where each pixel is an RGB-emitting stacked MicroLED device (left). The micro-display showing a video of fireworks at night, demonstrating the full-colour capability (right). N.B. Areas around the display/
Figure 119. TCL MiniLED TV schematic
Figure 120. TCL 8K MiniLED TV
Figure 121. The Cinema Wall MicroLED display
Figure 122. Photo-polymer mass transfer process
Figure 123. 7.56" Transparent Display
Figure 124. 7.56" Flexible MicroLED
Figure 125. 5.04" seamless splicing MicroLED
Figure 126. 7.56" Transparent MicroLED
Figure 127. VueReal Flipchip MicroLED (30x15 um2)
Figure 128. Vuzix uLED display engine