Micro-light-emitting diodes with III–nitride tunnel junction contacts grown by metalorganic chemical vapor deposition

Hwang, David J.; Mughal, Asad J.; Wong, Matthew S.; Alhassan, Abdullah I.; Nakamura, Shuji; DenBaars, Steven P.

doi:10.7567/apex.11.012102

Cited by 68 publications

(61 citation statements)

References 29 publications

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“…To reach a high resolution in displays, μ-LEDs are required with dimensions below 20 μm. So far, μ-LEDs with dimensions even smaller than 10 μm have been demonstrated [7]- [11]. Several groups have investigated the effect of the chip dimension on the external quantum efficiency (EQE) of a μ-LED [6], [8]- [13].…”

Section: Introductionmentioning

confidence: 99%

Light Extraction Efficiency of GaN-Based Micro-Scale Light-Emitting Diodes Investigated Using Finite-Difference Time-Domain Simulation

2020

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We conducted a systematic investigation of the light extraction efficiency (LEE) of GaN-based vertical micro-scale light-emitting diode (μ-LED) structures using threedimensional finite-difference time-domain (FDTD) simulations. The LEE of μ-LED structures was found to have a strong dependence on structural parameters such as the shape of the chip cross section, chip dimension, and p-GaN thickness. The LEE of a μ-LED with a circular cross section was lower than that of a μ-LED with a square cross section by 5∼10% owing to the coupling of light with high-quality-factor whispering gallery modes. The LEE of a μ-LED structure decreased as the chip dimension increased, which could be attributed to the increased portion of trapped light inside the LED chip and increased light absorption in the GaN with an increasing chip dimension. In addition, the LEE varied significantly with the thickness of the p-GaN layer, which could be explained by the strong dependence of the angular distribution of the emission pattern on the p-GaN thickness. The FDTD simulation method presented in this study is expected to be advantageously employed in designing μ-LED structures with high LEE.

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Section: Introductionmentioning

confidence: 99%

Light Extraction Efficiency of GaN-Based Micro-Scale Light-Emitting Diodes Investigated Using Finite-Difference Time-Domain Simulation

2020

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“…Germanium n-doped GaN tunnel junctions on top of visible GaN LEDs were already demonstrated by Neugebauer et al 20 using an all-MOCVD growth approachnonetheless, this growth method is not optimal for tunnel junctions due to the re-passivation of the Mg acceptors by the H present in the growth chamber. A post-growth annealing to reactivate these acceptors would then be necessary, 21 but the p-doped layers in TJ devices are always buried under a highly n-doped layer, hindering the diffusion of H. [22][23][24] Additionally, for Ge-doped AlGaN layers, the Ge activation energy increases with the concentration of Al, 25 which yields a new challenge. Nonetheless, high electron concentrations (>1x10 20 cm -3 ) can be achieved with Ge-doped GaN 14 and AlGaN 25 layers by MBE.…”

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confidence: 99%

Ge doped GaN and Al0.5Ga0.5N-based tunnel junctions on top of visible and UV light emitting diodes

Arcara

Damilano

Feuillet

et al. 2019

Journal of Applied Physics

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The use of tunnel junctions (TJs) is a potential solution in blue LEDs to poor p-contacts, replacing it by another n-contact. TJs are even more advantageous for UV emitting structures, which suffer from the considerably low injection efficiency in high Al concentration UV LEDs. In this work we report our work on Ge n-doped GaN and AlGaN TJs grown on top of blue and UV LEDs, respectively, by a hybrid growth. We have achieved state of the art mobility (67cm 2 /V.s) and resistivity (1.7x10 -4 Ω.cm) at a free electron concentration of 5.5x10 20 cm -3 in Ge-doped GaN. With an emission wavelength of 436nm, the GaN TJ slightly increased the optical power of the blue LED. The AlGaN TJs, on the other hand, improved the optical power of the UV LED (304nm) by at least a factor of 3, suggesting the enhancement of the hole injection efficiency by the use of TJs in UV emitting structures.

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“…We believe that the BHF treatment improved the voltage by reducing Mg diffusion into the n ++ -GaN layer, which could compensate electron carriers required to form an abrupt junction. 15,19,21) Finally, the best results were obtained from the sample treated in BHF with in-situ activation prior to TJ regrowth, which showed voltages of 3.4 V at 20 A=cm 2 and 4.5 V at 1 kA=cm 2 . These J-V characteristics are reasonably close to those of a diode with the MOCVD-MBE hybrid TJ contacts reported by Young et al (3.05 V at 20 A=cm 2 ), 15) but the voltage of the MOCVD TJ sample could be increased owing to structural differences, including poor n-contact on lightly doped n-GaN and extra resistance from the substrate.…”

Section: ++mentioning

confidence: 97%

GaN-based vertical-cavity surface-emitting lasers with tunnel junction contacts grown by metal-organic chemical vapor deposition

Lee

Forman

Lee

et al. 2018

Appl. Phys. Express

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We report the first demonstration of III-nitride vertical-cavity surface-emitting lasers (VCSELs) with tunnel junction (TJ) intracavity contacts grown completely by metal-organic chemical vapor deposition (MOCVD). For the TJs, n ++ -GaN was grown on in-situ activated p ++ -GaN after buffered HF surface treatment. The electrical properties and epitaxial morphologies of the TJs were first investigated on TJ LED test samples. A VCSEL with a TJ intracavity contact showed a lasing wavelength of 408 nm, a threshold current of >15 mA (10 kA/cm 2 ), a threshold voltage of 7.8 V, a maximum output power of 319 µW, and a differential efficiency of 0.28%.

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Micro-light-emitting diodes with III–nitride tunnel junction contacts grown by metalorganic chemical vapor deposition

Cited by 68 publications

References 29 publications

Light Extraction Efficiency of GaN-Based Micro-Scale Light-Emitting Diodes Investigated Using Finite-Difference Time-Domain Simulation

Light Extraction Efficiency of GaN-Based Micro-Scale Light-Emitting Diodes Investigated Using Finite-Difference Time-Domain Simulation

Ge doped GaN and Al0.5Ga0.5N-based tunnel junctions on top of visible and UV light emitting diodes

GaN-based vertical-cavity surface-emitting lasers with tunnel junction contacts grown by metal-organic chemical vapor deposition

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