Role of substrate quality on the performance of semipolar (112¯2) InGaN light-emitting diodes

Dinh, Duc V.; Corbett, Brian; Parbrook, P. J.; Koslow, Ingrid; Rychetsky, Monir; Guttmann, Martin; Wernicke, Tim; Kneissl, Michael; Mounir, Christian; Schwarz, Uli; Glaab, Johannes; Netzel, Carsten; Brunner, F.; Weyers, M.

doi:10.1063/1.4963757

Cited by 8 publications

(5 citation statements)

References 61 publications

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“…22Þ blue LEDs, which exhibited similar values (1.8 nm shift) in a similar range of drive currents. 18) Generally, to our knowledge, these values outperform previously reported blue LEDs grown on semipolar ð11 22Þ, as shown in the comparative summary in Table I. [18][19][20][21][22] Ray-tracing simulations were performed using a commercial software package 23) to evaluate the difference in the LEE between the 3S-PSS template and the planar template structures.…”

supporting

confidence: 51%

“…18) Generally, to our knowledge, these values outperform previously reported blue LEDs grown on semipolar ð11 22Þ, as shown in the comparative summary in Table I. [18][19][20][21][22] Ray-tracing simulations were performed using a commercial software package 23) to evaluate the difference in the LEE between the 3S-PSS template and the planar template structures. Ray-tracing simulations use the laws of geometrical optics to analyze the behavior of a statistical population of rays propagating in systems with feature sizes larger than the wavelength of light in the materials.…”

supporting

confidence: 51%

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444 nm InGaN light emitting diodes on low-defect-density $(11\bar{2}2)$ GaN templates on patterned sapphire

Khoury

Kuritzky

et al. 2017

Appl. Phys. Express

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Efficient InGaN-based 444 nm blue light-emitting diodes (LEDs) were fabricated on low-defect-density semipolar GaN templates grown on patterned r-sapphire. At 20 A/cm2, the packaged LEDs exhibited a light output power of 2.9 mW (17.8 mW at 100 A/cm2) and a record peak external quantum efficiency of 6.4% showing a negligible efficiency droop and blue shift with drive currents up to 100 A/cm2. In addition, we demonstrated light extraction simulations for the template, which showed that the structured pattern is not only beneficial for limiting the defect propagation but also increases the light extraction by 29% compared with GaN layers grown on planar substrates.

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supporting

confidence: 51%

supporting

confidence: 51%

444 nm InGaN light emitting diodes on low-defect-density $(11\bar{2}2)$ GaN templates on patterned sapphire

Khoury

Kuritzky

et al. 2017

Appl. Phys. Express

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“…Prior to the MOCVD growth, patterning of Si substrates was performed. Stripe grooves with (111) Si facets extending along the direction were fabricated by a conventional photolithography technique. At first, a 100 nm‐thick thermally oxidized SiO 2 mask on (113) Si substrate was fabricated into a stripe pattern by ICP‐RIE.…”

Section: Methodsmentioning

confidence: 99%

“…There are some experimental results of the remarkable high power LEDs with several semipolar crystal planes grown on bulk GaN substrates . However, semipolar LEDs fabricated on sapphire substrates have shown lower output powers compared to those of the LEDs grown on bulk GaN substrates . Growth of semipolar GaN films on foreign substrates or patterned substrates is not an easy task because the inherent high density of threading dislocations and stacking faults degrades the optical and electrical properties of the devices .…”

Section: Introductionmentioning

confidence: 99%

Reduction of basal plane defects in (11-22) semipolar InGaN/GaN MQWs fabricated on patterned (113) Si substrates by introducing AlGaN barrier layers

Uesugi

Hikosaka

Ono

et al. 2017

Phys. Status Solidi A

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GaN grown on nonpolar or semipolar faces have been widely developed as a promising material for the next generation optical and electronic devices. In this work, (11–22) semipolar InGaN/GaN MQWs were grown on patterned (113) Si substrates and fabricated into thin‐film‐type flip‐chip LEDs. From CL and TEM measurement, generation of basal plane defects (BPDs) around MQWs and Strain‐relaxation layers (SRLs) has been observed. The relationship between MQW structures and formation of BPDs has been investigated. By optimizing MQW structures, light output power and external quantum efficiency have been improved with thick InGaN well layers and GaN barrier layers. Introducing AlGaN barrier layers has enabled further reduction of BPDs in MQWs and, as a result, an enhancement of EQE has been achieved. The maximum EQE value of the sample with AlGaN barrier layers was 12.9%.This result indicates that the reduction of BPDs is an effective approach for obtaining the high‐efficiency semipolar LEDs on Si substrates.

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“…These electric fields are the cause of the quantum-confined Stark effect (QCSE), which reduces the quantum efficiency, and its effect increases with increasing AlN fraction. Growth of Al x Ga 1− x N in non- or semi-polar orientations is of interest for removing or decreasing the effect of the QCSE, as already successfully employed for visible devices using the InGaN alloy system 7 – 9 . However, moving away from the polar orientation leads to a high density of extended defects such as stacking faults (SFs) and misfit dislocations in addition to threading dislocations (TDs) also present in c -orientated hetero-epitaxial nitride materials 10 – 12 .…”

Section: Introductionmentioning

confidence: 99%

Spatially-resolved optical and structural properties of semi-polar $$\mathrm{(11}\bar{2}\mathrm{2)}$$ Al x Ga1−x N with x up to 0.56

Bruckbauer

Naresh-Kumar

et al. 2017

Sci Rep

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Pushing the emission wavelength of efficient ultraviolet (UV) emitters further into the deep-UV requires material with high crystal quality, while also reducing the detrimental effects of built-in electric fields. Crack-free semi-polar AlxGa1−xN epilayers with AlN contents up to x = 0.56 and high crystal quality were achieved using an overgrowth method employing GaN microrods on m-sapphire. Two dominant emission peaks were identified using cathodoluminescence hyperspectral imaging. The longer wavelength peak originates near and around chevron-shaped features, whose density is greatly increased for higher contents. The emission from the majority of the surface is dominated by the shorter wavelength peak, influenced by the presence of basal-plane stacking faults (BSFs). Due to the overgrowth technique BSFs are bunched up in parallel stripes where the lower wavelength peak is broadened and hence appears slightly redshifted compared with the higher quality regions in-between. Additionally, the density of threading dislocations in these region is one order of magnitude lower compared with areas affected by BSFs as ascertained by electron channelling contrast imaging. Overall, the luminescence properties of semi-polar AlGaN epilayers are strongly influenced by the overgrowth method, which shows that reducing the density of extended defects improves the optical performance of high AlN content AlGaN structures.

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Role of substrate quality on the performance of semipolar (112¯2) InGaN light-emitting diodes

Cited by 8 publications

References 61 publications

444 nm InGaN light emitting diodes on low-defect-density $(11\bar{2}2)$ GaN templates on patterned sapphire

444 nm InGaN light emitting diodes on low-defect-density $(11\bar{2}2)$ GaN templates on patterned sapphire

Reduction of basal plane defects in (11-22) semipolar InGaN/GaN MQWs fabricated on patterned (113) Si substrates by introducing AlGaN barrier layers

Spatially-resolved optical and structural properties of semi-polar $$\mathrm{(11}\bar{2}\mathrm{2)}$$ Al x Ga1−x N with x up to 0.56

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