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GaN-based micro-light-emitting diodes (micro-LEDs) have great advantages in visible light communication (VLC). However, the limited external quantum efficiency (EQE) and the modulation bandwidth of green micro-LEDs have been the obstacles of improvement in the data rates of the VLC system. In this work, a straightforward and efficacious approach is employed to improve the VLC performance of the micro-LEDs, that is, etching epitaxial layers to a sapphire substrate using deep-etching processes to fabricate each micro-LED electrically isolated arrays. Compared to micro-LEDs with a common n-type GaN layer, the deep-etched micro-LEDs exhibit enhanced light output power from the sapphire side and increased −3 dB bandwidth, owing to the reduced n-GaN waveguiding effect and parasitic capacitance, resulting in 47.03% and 57.33% improvements in EQE and −3 dB bandwidth at 4 kA/cm2, respectively. As a result, the deep-etched green micro-LED based VLC system achieved a maximum data rate of 6.58 Gbps by employing an orthogonal frequency division multiplexing modulation scheme and a pre-equalization method, which represents the highest data rate for a single green micro-LED.
Zhang et al. (Mon,) studied this question.