Your search keyword '"Nakamura, Shuji"' showing total 13 results

1. Progress in III-Nitride Tunnel Junctions for Optoelectronic Devices.

Author

Wong, Matthew S., Speck, James S., Nakamura, Shuji, and DenBaars, Steven P.

Subjects

*OPTOELECTRONIC devices, *SURFACE emitting lasers, *TUNNEL junctions (Materials science), *LIGHT emitting diodes, *MOLECULAR beam epitaxy, *CHEMICAL vapor deposition

Abstract

The recent progress in III-nitride tunnel junction (TJ) contacts for optoelectronic devices is summarized in this review paper. Due to the rapid developments of various III-nitride based optoelectronic devices for different emerging applications, TJs are of interest for these devices to achieve more efficient device performance. This review paper first briefly describes the working principles of TJs and the advantages of employing TJs in optoelectronic devices. The significant advancements in III-nitride TJs realized by metalorganic chemical vapor deposition (MOCVD) and molecular beam epitaxy (MBE) are addressed, as well as their TJ device performances. Lastly, the critical challenges for employing III-nitride TJs in wide bandgap ultraviolet (UV) light emitters are discussed for future investigations. [ABSTRACT FROM AUTHOR]

Published

2022

2. Structure of V-defects in long wavelength GaN-based light emitting diodes.

Author

Wu, Feng, Ewing, Jacob, Lynsky, Cheyenne, Iza, Michael, Nakamura, Shuji, DenBaars, Steven P., and Speck, James S.

Subjects

*LIGHT emitting diodes, *X-ray fluorescence, *ATOM-probe tomography, *SCANNING transmission electron microscopy, *TRANSMISSION electron microscopy, *INDIUM gallium nitride, *SUPERLATTICES

Abstract

The V-defect is a naturally occurring inverted hexagonal pyramid structure that has been studied in GaN and InGaN growth since the 1990s. Strategic use of V-defects in pre-quantum well superlattices or equivalent preparation layers has enabled record breaking efficiencies for green, yellow, and red InGaN light emitting diodes (LEDs) utilizing lateral injection of holes through the semi-polar sidewalls of the V-defects. In this article, we use advanced characterization techniques such as scattering contrast transmission electron microscopy, high angle annular dark field scanning transmission electron microscopy, x-ray fluorescence maps, and atom probe tomography to study the active region compositions, V-defect formation, and V-defect structure in green and red LEDs grown on (0001) patterned sapphire and (111) Si substrates. We identify two distinct types of V-defects. The "large" V-defects are those that form in the pre-well superlattice and promote hole injection, usually nucleating on mixed (Burgers vector b = ± a ± c) character threading dislocations. In addition, "small" V-defects often form in the multi-quantum well region and are believed to be deleterious to high-efficiency LEDs by providing non-radiative pathways. The small V-defects are often associated with basal plane stacking faults or stacking fault boxes. Furthermore, we show through scattering contrast transmission electron microscopy that during V-defect filling, the threading dislocation, which runs up the center of the V-defect, will "bend" onto one of the six { 10 1 ¯ 1 } semi-polar planes. This result is essential to understanding non-radiative recombination in V-defect engineered LEDs. [ABSTRACT FROM AUTHOR]

Published

2023

3. Dynamics of carrier injection through V-defects in long wavelength GaN LEDs.

Author

Marcinkevičius, Saulius, Tak, Tanay, Chow, Yi Chao, Wu, Feng, Yapparov, Rinat, DenBaars, Steven P., Nakamura, Shuji, and Speck, James S.

Subjects

*GALLIUM nitride, *LIGHT emitting diodes, *WAVELENGTHS, *QUANTUM wells, *INDIUM gallium nitride, *DIFFUSION coefficients, *PROJECT POSSUM

Abstract

The efficiency of high-power operation of multiple quantum well (QW) light emitting diodes (LEDs) to a large degree depends on the realization of uniform hole distribution between the QWs. In long wavelength InGaN/GaN QW LEDs, the thermionic interwell hole transport is hindered by high GaN barriers. However, in polar LED structures, these barriers may be circumvented by the lateral hole injection via semipolar 10 1 ¯ 1 QWs that form on the facets of V-defects. The efficiency of such carrier transfer depends on the transport time since transport in the semipolar QWs is competed by recombination. In this work, we study the carrier transfer from the semipolar to polar QWs by time-resolved photoluminescence in long wavelength (green to red) LEDs. We find that the carrier transfer through the semipolar QWs is fast, a few tens of picoseconds with the estimated room temperature ambipolar diffusion coefficient of ∼5.5 cm2/s. With diffusion much faster than recombination, the hole transport from the p-side of the structure to the polar QWs should proceed without a substantial loss, contributing to the high efficiency of long wavelength GaN LEDs. [ABSTRACT FROM AUTHOR]

Published

2024

4. Growth of highly relaxed InGaN pseudo-substrates over full 2-in. wafers.

Author

Chan, Philip, DenBaars, Steven P., and Nakamura, Shuji

Subjects

*LIGHT emitting diodes, *CHEMICAL vapor deposition, *QUANTUM wells, *BUFFER layers, *GALLIUM nitride, *INDIUM

Abstract

A highly relaxed InGaN buffer layer was demonstrated over a full two-inch c-plane sapphire substrate by metalorganic chemical vapor deposition. The InGaN buffer layer was grown on a 100 nm GaN decomposition stop layer with a 3 nm thick high indium composition InGaN underlayer. After thermal decomposition of the underlayer at 1000 °C, a 200 nm thick In0.04Ga0.96N buffer showed 85% biaxial relaxation measured by a high resolution x-ray diffraction reciprocal space map. When used as a pseudo-substrate for the regrowth of InGaN/InGaN multi-quantum wells, the sample showed a 75 nm red-shift in room temperature photoluminescence when compared to a co-loaded GaN template reference. The longer emission wavelength is associated with higher indium incorporation in the InGaN layers from the lessening of the compositional pulling effect caused by compressive strain. Using this technique, a simple red light emitting diode was demonstrated with an active layer growth temperature of 825 °C and a peak wavelength of 622 nm at a current density of 20 A cm−2. This work represents a unique method to relax a III-nitride based layer over a full substrate. [ABSTRACT FROM AUTHOR]

Published

2021

5. 10.6% external quantum efficiency germicidal UV LEDs grown on thin highly conductive n-AlGaN.

Author

Wang, Michael, Wu, Feng, Yao, Yifan, Zollner, Christian, Iza, Michael, Lam, Michael, DenBaars, Steven P., Nakamura, Shuji, and Speck, James S.

Subjects

*QUANTUM efficiency, *LIGHT emitting diodes, *THICK films, *THIN films, *ULTRAVIOLET radiation

Abstract

We report on the material challenges of the growth of highly conductive n-AlGaN in germicidal ultraviolet light emitting diodes (GUV LEDs), with the degradation of the surface morphology of thick highly doped n-AlGaN due to the Si anti-surfactant effect. Threading dislocation inclination, increasing relaxation, and eventual cracking were observed with epitaxial n-AlGaN films thicker than 400 nm, along with an increasing Ga composition with the same metalorganic flows. With the optimization of the n-AlGaN conductivity in previous works, thin n-AlGaN films with high conductivity along with a smoothing superlattice were incorporated in GUV LED devices, resulting in LEDs with 285 nm electroluminescence, a low forward voltage of 4.2 V with a peak external quantum efficiency (EQE) of 10.6% and a peak wall-plug efficiency of 8.6% below 1 A/cm2, and an EQE of 5.5% at 20 A/cm2. [ABSTRACT FROM AUTHOR]

Published

2023

6. Experimental evidence of hole injection through V-defects in long wavelength GaN-based LEDs.

Author

Marcinkevičius, Saulius, Ewing, Jacob, Yapparov, Rinat, Wu, Feng, Nakamura, Shuji, and Speck, James S.

Subjects

*OPTICAL sensors, *LIGHT emitting diodes, *ELECTROLUMINESCENCE, *OPTICAL detectors, *THERMIONIC emission, *WAVELENGTHS, *PHOTOLUMINESCENCE measurement, *QUANTUM wells

Abstract

Hole injection through V-defect sidewalls into all quantum wells (QWs) of long wavelength GaN light emitting diodes had previously been proposed as means to increase efficiency of these devices. In this work, we directly tested the viability of this injection mechanism by electroluminescence and time-resolved photoluminescence measurements on a device in which QW furthest away from the p-side of the structure was deeper, thus serving as an optical detector for presence of injected electron–hole pairs. Emission from the detector well confirmed that, indeed, the holes were injected into this QW, which could only take place through the 10 1 ¯ 1 V-defect sidewalls. Unlike direct interwell transport by thermionic emission, this transport mechanism allows populating all QWs of a multiple QW structure despite the high potential barriers in the long wavelength InGaN/GaN QWs. [ABSTRACT FROM AUTHOR]

Published

2023

7. Origins of the high-energy electroluminescence peaks in long-wavelength (∼495–685 nm) InGaN light-emitting diodes.

Author

Chow, Yi Chao, Tak, Tanay, Wu, Feng, Ewing, Jacob, Nakamura, Shuji, DenBaars, Steven P., Wu, Yuh-Renn, Weisbuch, Claude, and Speck, James S.

Subjects

*INDIUM gallium nitride, *ELECTROLUMINESCENCE, *EXCITED states, *LIGHT emitting diodes, *EPITAXY, *QUANTUM wells, *INDIUM

Abstract

We investigate the unexpected high-energy electroluminescence (EL) peaks observed in long-wavelength InGaN light-emitting diodes (LEDs) with ground state emission peaks between ∼495 and 685 nm by studying the EL spectra of LEDs with varying quantum well (QW) thicknesses and indium compositions. In addition to the ground state emission, two high-energy emission peaks were observed in the LEDs with thick QWs and high indium compositions. The less energetic high-energy emission peak (2.4–2.6 eV) is attributed to the optical transitions involving excited states. Factors influencing the excited state transitions, such as the QW thickness and indium compositions, were also examined by simulations to better understand the occurrence of these transitions. The more energetic high-energy emission peak (2.8–3.1 eV) originates from V-defect sidewalls and was verified through micro-photoluminescence measurements. Identification of the high-energy emission peaks is essential as it enables targeted epitaxial or growth optimizations to minimize or eliminate these undesirable emission peaks. This work demonstrates the importance of using thin QWs to suppress the unwanted high-energy emissions due to excited state transitions and V-defect sidewalls for long-wavelength InGaN LEDs. [ABSTRACT FROM AUTHOR]

Published

2023

8. Atomic layer etching (ALE) of III-nitrides.

Author

Ho, Wan Ying, Chow, Yi Chao, Biegler, Zachary, Qwah, Kai Shek, Tak, Tanay, Wissel-Garcia, Ashley, Liu, Iris, Wu, Feng, Nakamura, Shuji, and Speck, James S.

Subjects

*LIGHT emitting diodes, *PLASMA etching, *ETCHING, *ALE, *GAS absorption & adsorption, *ION bombardment, *QUANTUM wells, *INDIUM gallium nitride

Abstract

Atomic layer etching (ALE) was performed on (Al, In, Ga)N thin films using a cyclic process of alternating Cl2 gas absorption and Ar+ ion bombardment in an inductively coupled plasma etcher system. The etch damage was characterized by comparing photoluminescence of blue single quantum well light-emitting diodes before and after the etch as well as bulk resistivities of etched p-doped layers. It was found that etched surfaces were smooth and highly conformal, retaining the step-terrace features of the as-grown surface, thus realizing ALE. Longer exposures to the dry etching increased the bulk resistivity of etched surfaces layers slightly, with a damaged depth of ∼55 nm. With further optimization and damage recovery, ALE is a promising candidate for controlled etching with atomic accuracy. It was found that Al0.1Ga0.9N acts as an etch barrier for the ALE etch, making it a suitable etch to reveal buried V-defects in III-nitride light emitting diodes. [ABSTRACT FROM AUTHOR]

Published

2023

9. Study of Pore Geometry and Dislocations in Porous GaN Based Pseudo-Substrates Using TEM.

Author

Pasayat, Shubhra S., Wu, Feng, Gupta, Chirag, DenBaars, Steven P., Nakamura, Shuji, Keller, Stacia, and Mishra, Umesh K.

Subjects

*LIGHT emitting diodes, *QUANTUM wells, *TRANSMISSION electron microscopy, *SURFACE recombination, *INDIUM, *NITRIDES

Abstract

Nitride based light emitting diodes (LEDs) have demonstrated very high efficiency in the blue and green wavelength ranges. For full color LED based displays, efficient and small sized devices emitting in the three primary colors - red, green and blue are required. While phosphide based red LEDs are highly efficient, high surface recombination velocities limit their scaling to small dimensions. Nitride emitters can be scaled to smaller sizes, however for longer emission wavelength such as yellow, orange, and red, the indium content in the active region of the devices needs to be >30%. Due to the large lattice mismatch between GaN and InN, the needed high indium content introduces a large strain in the structure, often resulting in poor material quality. Recently, a novel technique to mitigate this lattice mismatch induced strain was demonstrated with the use of compliant porous GaN underlayer based substrates. In our previous reports, we have discussed the surface morphology, strain state evolution and device demonstrations using these substrates, however a detailed discussion regarding the pore cross-sections and dislocation propagation for each generation of these porous GaN substrates was yet to be reported. In this work, we will discuss the cross-sectional transmission electron microscopy (TEM) results of these substrates across multiple stages of the substrate technology development. [ABSTRACT FROM AUTHOR]

Published

2022

10. Polarization-Enhanced p-AlGaN Superlattice Optimization for GUV LED.

Author

Yao, Yifan, Zollner, Christian J., Wang, Michael, Iza, Michael, Speck, James S., DenBaars, Steven P., and Nakamura, Shuji

Subjects

*LIGHT emitting diodes, *GALLIUM alloys, *WIDE gap semiconductors, *ALUMINUM gallium nitride, *ALUMINUM nitride

Abstract

AlGaN germicidal ultraviolet (GUV) light emitting diodes (LEDs) are one of the most promising disinfection technologies in fighting the COVID-19 pandemic; however, GUV LEDs are still lacking in efficiency due to low p-type doping efficiency in p-AlGaN. The most successful approach for producing conductive p-type AlGaN is the implementation of a polarization-enhanced short period Al $_{\mathbf {x}}$ Ga $_{\mathbf {1-}\mathbf {x}}$ N/Al $_{\mathbf {y}}$ Ga $_{\mathbf {1-}\mathbf {y}}$ N superlattice (SL) structure, which enhances hole injection and reduces device operating voltage. In this report, we investigated different aspects of the superlattice including the Al $_{\mathbf {x}}$ Ga $_{\mathbf {1-}\mathbf {x}}$ N and Al $_{\mathbf {y}}$ Ga $_{\mathbf {1-}\mathbf {y}}$ N alloy constituent compositions, ${x}$ and ${y}$ , period thickness, total thickness, and Mg dopant concentration in terms of LED performance as well as electrical, optical, and morphological characteristics. The polarization-enhanced p-type doping in the AlGaN superlattice was also investigated computationally, giving excellent agreement with experimental results. Highly efficient UVC LEDs (279 nm) with EQE of 2% at 5 A/cm2 were demonstrated. A maximum output power of 5.5 mW (56 mW/mm2) was achieved at 100 mA. [ABSTRACT FROM AUTHOR]

Published

2022

11. Demonstration of ultra-small 5 × 5 μm2 607 nm InGaN amber micro-light-emitting diodes with an external quantum efficiency over 2%.

Author

Li, Panpan, Li, Hongjian, Yang, Yunxuan, Zhang, Haojun, Shapturenka, Pavel, Wong, Matthew, Lynsky, Cheyenne, Iza, Mike, Gordon, Michael J., Speck, James S., Nakamura, Shuji, and DenBaars, Steven P.

Subjects

*QUANTUM efficiency, *INDIUM gallium nitride, *LIGHT emitting diodes, *DIODES, *AUGMENTED reality, *SEMICONDUCTOR lasers, *VIRTUAL reality

Abstract

Red micro-size light-emitting diodes (μLEDs) less than 10 × 10 μm2 are crucial for augmented reality (AR) and virtual reality (VR) applications. However, they remain very challenging since the common AlInGaP red μLEDs with such small size suffer from a dramatic reduction in the external quantum efficiency. In this work, we demonstrate ultra-small 5 × 5 μm2 607 nm amber μLEDs using InGaN materials, which show an EQE over 2% and an ultra-low reverse current of 10−9 A at −5 V. This demonstration suggests promising results of ultra-small InGaN μLEDs for AR and VR displays. [ABSTRACT FROM AUTHOR]

Published

2022

12. Demonstration of high efficiency cascaded blue and green micro-light-emitting diodes with independent junction control.

Author

Li, Panpan, Li, Hongjian, Yao, Yifan, Zhang, Haojun, Lynsky, Cheyenne, Qwah, Kai Shek, Speck, James S., Nakamura, Shuji, and DenBaars, Steven P.

Subjects

*LIGHT emitting diodes, *CHEMICAL vapor deposition, *DIODES, *QUANTUM efficiency

Abstract

We demonstrate efficient cascaded blue/green micro-size light-emitting diodes (μLEDs) with independent junction control. The cascaded μLEDs, consisted of blue μLEDs, a tunnel junction, and green μLEDs, were fully grown by metalorganic chemical vapor deposition. Blue, green, and blue/green emissions can be independently controlled in the same device. The blue μLEDs (60 × 60 μm2) and green μLEDs (40 × 40 μm2) exhibit a forward voltage of 4.1 and 3.1 V at 20 A/cm2 and a high peak external quantum efficiency of 42% and 14%, respectively. This demonstration paves the way for monolithic integration of full color cascaded μLEDs. [ABSTRACT FROM AUTHOR]

Published

2021

13. N-face GaN substrate roughening for improved performance GaN-on-GaN LED.

Author

Alias, Ezzah Azimah, Samsudin, Muhammad Esmed Alif, DenBaars, Steven, Speck, James, Nakamura, Shuji, and Zainal, Norzaini

Subjects

*GALLIUM nitride, *QUANTUM efficiency, *POTASSIUM hydroxide, *LIGHT emitting diodes, *ETCHING reagents, *AMMONIUM hydroxide

Abstract

Purpose: This study aims to focus on roughening N-face (backside) GaN substrate prior to GaN-on-GaN light-emitting diode (LED) growth as an attempt to improve the LED performance. Design/methodology/approach: The N-face of GaN substrate was roughened by three different etchants; ammonium hydroxide (NH4OH), a mixture of NH4OH and H2O2 (NH4OH: H2O2) and potassium hydroxide (KOH). Hexagonal pyramids were successfully formed on the surface when the substrate was subjected to the etching in all cases. Findings: Under 30 min of etching, the highest density of pyramids was obtained by NH4OH: H2O2 etching, which was 5 × 109 cm–2. The density by KOH and NH4OH etchings was 3.6 × 109 and 5 × 108 cm–2, respectively. At standard operation of current density at 20 A/cm2, the optical power and external quantum efficiency of the LED on the roughened GaN substrate by NH4OH: H2O2 were 12.3 mW and 22%, respectively, which are higher than its counterparts. Originality/value: This study demonstrated NH4OH: H2O2 is a new etchant for roughening the N-face GaN substrate. The results showed that such etchant increased the density of the pyramids on the N-face GaN substrate, which subsequently resulted in higher optical power and external quantum efficiency to the LED as compared to KOH and NH4OH. [ABSTRACT FROM AUTHOR]

Published

2021