Research Progress of Micro-LED Display Technology

Zhang, Shenghao; Zheng, Hua; Zhou, Lijun; Li, H. N.; Chen, Y. F.; Wei, Chuanliang; Wu, Tong; Lv, Wei; Zhang, Geng; Zhang, Shaoqiang; Gong, Zheng; Jia, Baohua; Han, Lin; Gao, Zhiwen; Xu, Wei; Ning, Honglong

doi:10.3390/cryst13071001

Cited by 14 publications

(9 citation statements)

References 136 publications

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“…Batch transfer technology is desirable to be employed, because transferring TE legs one by one is of low efficiency, poor uniformity, and high alignment accuracy requirements. However, the state-of-the-art batch transfer technologies based on vacuum adsorption, electromagnetic force, van der Waals force, laser irradiation, sticky glue, or self-assembly remain plagued with some drawbacks 38 – 40 , including difficulties in transferring high-density micro-component array, low transfer yield due to poor adhesion control, surface pollution of the components, complex and expensive equipment, and inability to transfer non-planar components. Herein, we come up with a batch transfer strategy based on phase change materials (PCMs).…”

Section: Resultsmentioning

confidence: 99%

General strategy for developing thick-film micro-thermoelectric coolers from material fabrication to device integration

Sun,

Yan,

Kang

et al. 2024

Nat Commun

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Micro-thermoelectric coolers are emerging as a promising solution for high-density cooling applications in confined spaces. Unlike thin-film micro-thermoelectric coolers with high cooling flux at the expense of cooling temperature difference due to very short thermoelectric legs, thick-film micro-thermoelectric coolers can achieve better comprehensive cooling performance. However, they still face significant challenges in both material preparation and device integration. Herein, we propose a design strategy which combines Bi2Te3-based thick film prepared by powder direct molding with micro-thermoelectric cooler integrated via phase-change batch transfer. Accurate thickness control and relatively high thermoelectric performance can be achieved for the thick film, and the high-density-integrated thick-film micro-thermoelectric cooler exhibits excellent performance with maximum cooling temperature difference of 40.6 K and maximum cooling flux of 56.5 W·cm−2 at room temperature. The micro-thermoelectric cooler also shows high temperature control accuracy (0.01 K) and reliability (over 30000 cooling cycles). Moreover, the device demonstrates remarkable capacity in power generation with normalized power density up to 214.0 μW · cm−2 · K−2. This study provides a general and scalable route for developing high-performance thick-film micro-thermoelectric cooler, benefiting widespread applications in thermal management of microsystems.

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Section: Resultsmentioning

confidence: 99%

General strategy for developing thick-film micro-thermoelectric coolers from material fabrication to device integration

Sun,

Yan,

Kang

et al. 2024

Nat Commun

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“…However, this section only briefly describes detection and repair technologies; for more detailed information, please refer to previous studies. [223][224][225] For commercial applications, a mass transfer yield of 99.9999% and the detection and repair of bad pixels after transfer are required. 223 Bad pixels are known to be caused by open circuits or short circuits that can occur during the LED fabrication and mass transfer process.…”

Section: Detection and Repair Processesmentioning

confidence: 99%

Recent advances in micro-pixel light emitting diode technology

Park,

Pristovsek,

Amano

et al. 2024

Applied Physics Reviews

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Display technology has developed rapidly in recent years, with III–V system-based micro-light-emitting diodes (μLEDs) attracting attention as a means to overcome the physical limitations of current display systems related to their lifetime, brightness, contrast ratio, response time, and pixel size. However, for μLED displays to be successfully commercialized, their technical shortcomings need to be addressed. This review comprehensively discusses important issues associated with μLEDs, including the use of the ABC model for interpreting their behavior, size-dependent degradation mechanisms, methods for improving their efficiency, novel epitaxial structures, the development of red μLEDs, advanced transfer techniques for production, and the detection and repair of defects. Finally, industrial efforts to commercialize μLED displays are summarized. This review thus provides important insights into the potential realization of next-generation display systems based on μLEDs.

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“…In the realm of display technologies, the most important thing is to make micro-LEDs as accurately as possible using the top-down approach, where lithography, etching, and deposition are combined in an intricate manner. Lithography reveals the microLED pattern blueprint, which serves as a starting point for the complex manufacturing process [137]. The rest of the actions heavily rely on this accu racy-based step, as it determines microLEDs' properties and layout.…”

Section: Top-down Approach In Micro-led Patternsmentioning

confidence: 99%

“…This pushes the boundaries of visual display capabilities, and each step contributes to the synergy of processing and technology. It starts with lithography and ends with metal contacts deposition [137].…”

Section: Top-down Approach In Micro-led Patternsmentioning

confidence: 99%

Nanomaterial Integration in Micro LED Technology: Enhancing Efficiency and Applications

Mishra

2023

SSRN Journal

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Research Progress of Micro-LED Display Technology

Cited by 14 publications

References 136 publications

General strategy for developing thick-film micro-thermoelectric coolers from material fabrication to device integration

General strategy for developing thick-film micro-thermoelectric coolers from material fabrication to device integration

Recent advances in micro-pixel light emitting diode technology

Nanomaterial Integration in Micro LED Technology: Enhancing Efficiency and Applications

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