Mateusz Hajdel scite author profile

In this paper we show that, despite a high piezoelectric field, a wide InGaN quantum well (QW) can be more effective as the active region of laser diodes (LDs) than the thin ones usually used. The optical gain in the LDs with a single wide QW is studied. It is shown that the differential gain in a LD with 10.4 nm QW is higher than in a LD with three 2.6 nm thick QWs. The high optical gain in a wide QW is interpreted as originating from transitions through excited states. Additionally, a substantial difference in lasing spectra between LDs with wide and thin QWs is found.

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Ion implantation of tunnel junction as a method for defining the aperture of III-nitride-based micro-light-emitting diodes

Slawinska

Muzioł

Siekacz

et al. 2022

Opt. Express

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We report on III-nitride-based micro-light-emitting diodes (µLEDs) operating at 450 nm wavelength with diameters down to 2 µm. Devices with a standard LED structure followed by a tunnel junction were grown by plasma-assisted molecular beam epitaxy. The emission size of µLEDs was defined by shallow He+ implantation of the tunnel junction region. The ion implantation process allows to create flat devices, applicable to further epitaxial regrowth. The shift of current density for the maximum external quantum efficiency as a function of µLEDs diameter was observed. This effect may be a fingerprint of the change in the external efficiency related to the lateral carrier diffusion (limited by holes) in InGaN quantum wells.

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Vertical Integration of Nitride Laser Diodes and Light Emitting Diodes by Tunnel Junctions

et al. 2020

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We demonstrate the applications of tunnel junctions (TJs) for new concepts of monolithic nitride-based multicolor light emitting diode (LED) and laser diode (LD) stacks. The presented structures were grown by plasma-assisted molecular beam epitaxy (PAMBE) on GaN bulk crystals. We demonstrate a stack of four LDs operated at pulse mode with emission wavelength of 453 nm. The output power of 1.1 W and high slope efficiency of 2.3 W/A is achieved for devices without dielectric mirrors. Atomically flat surface after the epitaxy of four LD stack and low dislocation density is measured as a result of proper TJ design with optimized doping level. The strain compensation design with InGaN waveguides and AlGaN claddings is shown to be crucial to avoid cracking and lattice relaxation of the 5 µm thick structure. Vertical connection of n-LDs allows for cascade emission of photons and increases the quantum efficiency n-times. The two-color (blue and green) LEDs are demonstrated. Application of TJs simplifies device processing, reducing the need for applications of p-type contact. The key factor enabling demonstration of such devices is hydrogen-free PAMBE technology, in which activation of buried p-type layers is not necessary.

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Mateusz Hajdel

Stack of two III-nitride laser diodes interconnected by a tunnel junction

Optical properties of III-nitride laser diodes with wide InGaN quantum wells

Ion implantation of tunnel junction as a method for defining the aperture of III-nitride-based micro-light-emitting diodes

Vertical Integration of Nitride Laser Diodes and Light Emitting Diodes by Tunnel Junctions

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