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Etching-free pixel definition in InGaN green micro-LEDs

Zhiyuan Liu, Yi Lu, Haicheng Cao, Glen Isaac Maciel García, Tingang Liu, Xiao Tang, Na Xiao, Raul Aguileta Vazquez, Mingtao Nong, Xiaohang Li

2024Light Science & Applications33 citationsDOIOpen Access PDF

Abstract

Abstract The traditional plasma etching process for defining micro-LED pixels could lead to significant sidewall damage. Defects near sidewall regions act as non-radiative recombination centers and paths for current leakage, significantly deteriorating device performance. In this study, we demonstrated a novel selective thermal oxidation (STO) method that allowed pixel definition without undergoing plasma damage and subsequent dielectric passivation. Thermal annealing in ambient air oxidized and reshaped the LED structure, such as p -layers and InGaN/GaN multiple quantum wells. Simultaneously, the pixel areas beneath the pre-deposited SiO 2 layer were selectively and effectively protected. It was demonstrated that prolonged thermal annealing time enhanced the insulating properties of the oxide, significantly reducing LED leakage current. Furthermore, applying a thicker SiO 2 protective layer minimized device resistance and boosted device efficiency effectively. Utilizing the STO method, InGaN green micro-LED arrays with 50-, 30-, and 10-µm pixel sizes were manufactured and characterized. The results indicated that after 4 h of air annealing and with a 3.5-μm SiO 2 protective layer, the 10-µm pixel array exhibited leakage currents density 1.2 × 10 −6 A/cm 2 at −10 V voltage and a peak on-wafer external quantum efficiency of ~6.48%. This work suggests that the STO method could become an effective approach for future micro-LED manufacturing to mitigate adverse LED efficiency size effects due to the plasma etching and improve device efficiency. Micro-LEDs fabricated through the STO method can be applied to micro-displays, visible light communication, and optical interconnect-based memories. Almost planar pixel geometry will provide more possibilities for the monolithic integration of driving circuits with micro-LEDs. Moreover, the STO method is not limited to micro-LED fabrication and can be extended to design other III-nitride devices, such as photodetectors, laser diodes, high-electron-mobility transistors, and Schottky barrier diodes.

Topics & Concepts

Materials scienceOptoelectronicsPassivationWaferLight-emitting diodeQuantum efficiencyAnnealing (glass)Plasma etchingDiodeDielectricOxidePlasmaLeakage (economics)Etching (microfabrication)Layer (electronics)NanotechnologyComposite materialQuantum mechanicsPhysicsMacroeconomicsMetallurgyEconomicsGaN-based semiconductor devices and materialsGa2O3 and related materialsSemiconductor materials and devices