Comparison of Beyond 1 GHz C-Plane Freestanding and Sapphire-Substrate GaN-Based micro-LEDs for High-Speed Visible Light Communication

With ever-growing demand for 6 G networks technology, visible light communication (VLC) as a vital component of 6 G has challenging requirement for superior performance of light source. Herein, 20 \mum blue micro-LED fabricated on 2-inch c -plane GaN freestanding substrate with high bandwidth over 1...

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Veröffentlicht in:	Journal of lightwave technology 2023-03, Vol.41 (5), p.1-8
Hauptverfasser:	Shan, Xinyi, Wang, Guobin, Zhu, Shijie, Qiu, Pengjiang, Lin, Runze, Wang, Zhou, Yuan, Zexing, Yan, Qi-ang, Cui, Xugao, Wang, Jianfeng, Bi, Wengang, Liu, Ran, Xu, Ke, Tian, Pengfei
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Schlagworte:	<inline-formula xmlns:ali="http://www.niso.org/schemas/ali/1.0/" xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink" xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance"> <tex-math notation="LaTeX"> {c}</tex-math> </inline-formula>-plane GaN freestanding substrate Bandwidths Communication Crystal dislocations Dislocation density Gallium nitrides High speed Light emitting diodes Light sources micro-LED Optical communication Optoelectronics Sapphire Substrates Threading dislocations VLC
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creator	Shan, Xinyi Wang, Guobin Zhu, Shijie Qiu, Pengjiang Lin, Runze Wang, Zhou Yuan, Zexing Yan, Qi-ang Cui, Xugao Wang, Jianfeng Bi, Wengang Liu, Ran Xu, Ke Tian, Pengfei
description	With ever-growing demand for 6 G networks technology, visible light communication (VLC) as a vital component of 6 G has challenging requirement for superior performance of light source. Herein, 20 \mum blue micro-LED fabricated on 2-inch c -plane GaN freestanding substrate with high bandwidth over 1 GHz was first demonstrated, and the systematic comparisons to sapphire-substrate micro-LED from the epitaxial materials characterization to optoelectronic properties as well as communication performance were further conducted. GaN-substrate LED wafer has high crystal quality with lower threading dislocation density (TDD), which is two orders of magnitude lower than that of sapphire-substrate LED wafer. The much lower TDD of GaN-substrate LED wafer and better heat dissipation of GaN substrate offer GaN-substrate micro-LED great advantages in optoelectronic properties as well as communication performance. GaN-substrate micro-LED exhibited higher light output power (LOP) especially at high operating current, which is improved by \sim21% at 96 mA compared to that of sapphire substrate. Also, GaN-substrate micro-LED achieved a relatively higher bandwidth of 1.282 GHz while maintaining higher LOP with lower operating voltage. And a higher data rate of 4.48 Gbps under 1 m free space link was obtained by GaN-substrate micro-LED, proving it being a promising candidate in high-speed VLC.
doi_str_mv	10.1109/JLT.2022.3224612
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Herein, 20 <inline-formula><tex-math notation="LaTeX">\mu</tex-math></inline-formula>m blue micro-LED fabricated on 2-inch c -plane GaN freestanding substrate with high bandwidth over 1 GHz was first demonstrated, and the systematic comparisons to sapphire-substrate micro-LED from the epitaxial materials characterization to optoelectronic properties as well as communication performance were further conducted. GaN-substrate LED wafer has high crystal quality with lower threading dislocation density (TDD), which is two orders of magnitude lower than that of sapphire-substrate LED wafer. The much lower TDD of GaN-substrate LED wafer and better heat dissipation of GaN substrate offer GaN-substrate micro-LED great advantages in optoelectronic properties as well as communication performance. GaN-substrate micro-LED exhibited higher light output power (LOP) especially at high operating current, which is improved by <inline-formula><tex-math notation="LaTeX">\sim</tex-math></inline-formula>21% at 96 mA compared to that of sapphire substrate. Also, GaN-substrate micro-LED achieved a relatively higher bandwidth of 1.282 GHz while maintaining higher LOP with lower operating voltage. 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title	Comparison of Beyond 1 GHz C-Plane Freestanding and Sapphire-Substrate GaN-Based micro-LEDs for High-Speed Visible Light Communication
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