2007
DOI: 10.1109/lpt.2007.893820
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High-Efficiency 1-mm$^{2}$ AlGaInP LEDs Sandwiched by ITO Omni-Directional Reflector and Current-Spreading Layer

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Cited by 32 publications
(23 citation statements)
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“…Recent results have successfully demonstrated that released, thin‐film LEDs are integrated with flexible, stretchable, and even biodegradable substrates with better biocompatibilities like improved skin conformance and reduced lesion during implantation . Thin‐film, freestanding red and infrared (IR) LEDs based on gallium arsenide can be easily formed by selective sacrificial etching; however, conventional techniques for thin‐film GaN based purple/blue/green LED release and integration typically rely on sophisticated process steps including laser liftoff (LLO) (for GaN on sapphire), chemical etching (for GaN on Si), wafer bonding, layer transfer, device pick and place, etc., thus limiting their use. While GaN LED epitaxial liftoff and integration with flexible substrates have been extensively exploited for various planar device architectures like GaN LEDs on graphene, BN, glasses with nanovoids, Si, SiC‐on‐insulator, the performance of these devices is still inferior to their counterparts on conventional sapphire substrates, in terms of their current–voltage characteristics, quantum efficiencies, etc.…”
mentioning
confidence: 99%
“…Recent results have successfully demonstrated that released, thin‐film LEDs are integrated with flexible, stretchable, and even biodegradable substrates with better biocompatibilities like improved skin conformance and reduced lesion during implantation . Thin‐film, freestanding red and infrared (IR) LEDs based on gallium arsenide can be easily formed by selective sacrificial etching; however, conventional techniques for thin‐film GaN based purple/blue/green LED release and integration typically rely on sophisticated process steps including laser liftoff (LLO) (for GaN on sapphire), chemical etching (for GaN on Si), wafer bonding, layer transfer, device pick and place, etc., thus limiting their use. While GaN LED epitaxial liftoff and integration with flexible substrates have been extensively exploited for various planar device architectures like GaN LEDs on graphene, BN, glasses with nanovoids, Si, SiC‐on‐insulator, the performance of these devices is still inferior to their counterparts on conventional sapphire substrates, in terms of their current–voltage characteristics, quantum efficiencies, etc.…”
mentioning
confidence: 99%
“…Since non-uniformity occurs due to the lateral resistance of p-type layer, modification of physical thickness might not be the right solution. Many researches have tried to solve this problem by using spreading layers [17][18][19]. Until now, indium-tin-oxide (ITO) has been used broadly as a current spreading layer for its transparency and low resistance [20][21][22].…”
Section: Introductionmentioning
confidence: 99%
“…However, the external efficiency of AlGaInP LED is limited by the light absorption of a GaAs substrate and the narrow critical angle of total internal reflection at the semiconductor-air interface. The output-power efficiency of AlGaInP LED can be improved using a once or twice wafer-transferring technique to reduce the light absorption of GaAs substrate [1] [2]. The external efficiency of AlGaInP LED is mainly limited by difficulty of light extraction.…”
Section: Introductionmentioning
confidence: 99%