Litcius/Paper detail

633-nm InGaN-based red LEDs grown on thick underlying GaN layers with reduced in-plane residual stress

Daisuke Iida, Zhe Zhuang, Pavel Kirilenko, Martin Velazquez‐Rizo, Mohammed A. Najmi, Kazuhiro Ohkawa

2020Applied Physics Letters148 citationsDOIOpen Access PDF

Abstract

This work investigates the influence of residual stress on the performance of InGaN-based red light-emitting diodes (LEDs) by changing the thickness of the underlying n-GaN layers. The residual in-plane stress in the LED structure depends on the thickness of the underlying layer. Decreased residual in-plane stress resulting from the increased thickness of the underlying n-GaN layers improves the crystalline quality of the InGaN active region by allowing for a higher growth temperature. The electroluminescence intensity of the InGaN-based red LEDs is increased by a factor of 1.3 when the thickness of the underlying n-GaN layer is increased from 2 to 8 μm. Using 8-μm-thick underlying n-GaN layers, 633-nm-wavelength red LEDs are realized with a light-output power of 0.64 mW and an external quantum efficiency of 1.6% at 20 mA. The improved external quantum efficiency of the LEDs can be attributed to the lower residual in-plane stress in the underlying GaN layers.

Topics & Concepts

Light-emitting diodeMaterials scienceOptoelectronicsResidual stressElectroluminescenceWide-bandgap semiconductorDiodeStress (linguistics)Layer (electronics)Quantum efficiencyOpticsComposite materialLinguisticsPhysicsPhilosophyGaN-based semiconductor devices and materialsGa2O3 and related materialsMetal and Thin Film Mechanics