Near‐Complete Elimination of Size‐Dependent Efficiency Decrease in GaN Micro‐Light‐Emitting Diodes

Zhu, Jun; Takahashi, Tokio; Ohori, Daisuke; Endo, Kazuhiko; Samukawa, Seiji; Shimizu, Mitsuaki; Wang, Xue‐Lun

doi:10.1002/pssa.201900380

Cited by 43 publications

(34 citation statements)

References 23 publications

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“…[62,63] Surface passivation via atomic layer deposition, wet chemical etching with KOH or (NH 4 ) 2 S, and neutral beam etching have been shown to be efficient methods for suppressing leakage current and surface defects, leading to size-independent peak EQE. [60,[63][64][65][66][67][68] As a result, blue InGaN Micro-LEDs demonstrated >40% EQE in the size range of 10-100 µm, [60] while the peak EQEs of AlGaInP Micro-LEDs remained less than 12%. Thus, for the optimal design of full-color Micro-LED displays, different size chips should be used for each color, leading to highly complex drive circuit designs.…”

Section: Full-color Color-conversion Micro-led Arraysmentioning

confidence: 99%

Micro‐Light‐Emitting Diodes Based on InGaN Materials with Quantum Dots

Liu

Hyun

Sheng

et al. 2021

Adv Materials Technologies

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gallium arsenide, GaAs; indium antimonide, InSb) generation semiconductor materials, third-generation semiconductor materials, such as GaN semiconductors, have improved physical and chemical characteristics, such as a wider band gap, higher frequency, higher efficiency, higher breakdown voltage, higher thermal conductivity, higher thermal resistance, and higher radiation resistance. [1,2] Therefore, they are better suited for electronic or optoelectronic devices that operate in harsh environments due to their superior energy efficiency.In particular, GaN and related alloys, also known as III-nitrides, are essential materials in many modern optoelectronic applications due to the superior benefits provided by these materials and are commercially successful in the sectors of solid lighting and laser technologies. [3,4] III-nitrides can crystallize in either wurtzite (WZ) or zinc-blende (ZB) phases, with the hexagonal WZ phase being more thermodynamically stable. [5] The band gap remains direct across the entire composition range from aluminum nitride (6.4 eV, ≈3.5 eV for GaN) to indium nitride (≈0.65 eV), with the band gap energy ranging from the deep-ultraviolet to the near infrared spectrum. [3,4,6] Because of these properties, III-nitrides are particularly useful for optoelectronic devices such as LEDs, laser diodes (LDs), and photodetectors, where a direct band gap is essential for efficient device operation. [7,8] The rapid growth of III-nitride technology in optoelectronics has been accelerated by the introduction of blue LEDs with indium gallium nitride (InGaN) as the active layer, which has become important devices in various applications since the photoluminescence from high-quality InGaN films was shown in 1992 and the first blue LEDs were demonstrated in 1993. [9,10] Due to their high efficiency, chemical inertness, and long operating lifetime, InGaN-based LEDs have been widely used in our daily life, such as in traffic signals, full-color displays, back-light sources for liquid-crystal displays, and mobile electronic devices, as well as in general lighting, including automobile lamps, architecture illumination, and household lighting. [11][12][13][14] These LEDs are not only a new type of light source but also a prospective contributor to global energy savings. [11] In recent years, the need for high pixel density, high power efficiency, high luminance, and high refresh rate next generation displays (i.e., wearable/flexible, automotive head-up, and augmented/virtual reality (AR/VR) displays) has piqued the Micro-light-emitting diodes (Micro-LEDs) based on gallium nitride (GaN) materials offer versatile platforms for various applications, including displays, data communication tools, photodetectors, and sensors. In particular, the introduction of Micro-LEDs in the optoelectronic industry enables the development of novel short-distance wireless communication applications for the Internet of Things as well as near-to-eye displays for virtual reality and augmented reality. Micro-LEDs used in conjunction with...

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Section: Full-color Color-conversion Micro-led Arraysmentioning

confidence: 99%

Micro‐Light‐Emitting Diodes Based on InGaN Materials with Quantum Dots

Liu

Hyun

Sheng

et al. 2021

Adv Materials Technologies

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“…Recently, it has been reported that chemical treatment and sidewall passivation eliminate the size‐dependent efficiency decrease for μ‐LEDs with a size down to 10 μm. [ 7,8 ] However, μ‐LEDs with a size smaller than 10 μm still suffer severe efficiency loss even with chemical treatments and passivation. [ 6 ] The previous studies have shown that the decreased EQE of μ‐LEDs with size was attributed to the increased nonradiative surface recombination with decreasing size.…”

Section: Figurementioning

confidence: 99%

Role of Intrinsic Surface States in Efficiency Attenuation of GaN‐Based Micro‐Light‐Emitting‐Diodes

Jiang

Hyun

Zhang

et al. 2020

Physica Rapid Research Ltrs

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The effects of an intrinsic nonpolar surface on internal quantum efficiency (IQE) are numerically investigated for gallium nitride (GaN)‐based micro‐light emitting‐diodes (μ‐LEDs). It is found that due to the modulation of the surface density of states, the surface energy band bends upward, and valence band holes are naturally pushed toward the surface and are accumulated at the surface, resulting in significant nonradiative recombination. Consequently, the intrinsic surface states remarkably affect the IQE of μ‐LEDs with a size of less than 30 μm due to the large surface‐to‐volume ratio, whereas the IQE of devices with a size of more than 30 μm is relatively insensitive to the intrinsic surface states. IQE starts to decrease for devices with a size of 30 μm, even without considering sidewall damage. In particular, starting from a size of 10 μm, μ‐LEDs suffer a significant efficiency loss and the peak current density shifts to a higher value. The results open the way to improving device performance of μ‐LEDs down to 1 μm and beyond, by incorporating surface band engineering combined with surface passivation over the full range of microdisplay applications.

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“…[18,19] So far, a few methods have been attempted for removing the sidewall damage induced by the dry-etching, such as neutral beam etching and KOH chemical treatment. [25,26] Though they have demonstrated to be effective in mitigating the etching damage, the etching approach to fabrication of μLEDs still requires a sidewall passivation and isolation, which can bring about extra processing and performance issues as well. [20,21] Recently, we have developed a different approach to fabrication of InGaN/GaN multiquantum wells (MQWs) μLEDs: a selective overgrowth on patterned templates instead of mesa-etching.…”

Section: Introductionmentioning

confidence: 99%

“…The green μLEDs have demonstrated high external quantum efficiency and high luminescence. [3,25] We have also grown InGaNbased HEMT-μLEDs to take advantage of higher driving current densities expected of μLEDs for VLC. [7] In this work, currentvoltage and capacitance-voltage characteristics have been investigated systematically on the overgrown μLEDs with different sizes, which have also been compared with those μLEDs fabricated by means of using a conventionally dry-etching approach.…”

Section: Introductionmentioning

confidence: 99%

Investigation of Electrical Properties of InGaN‐Based Micro‐Light‐Emitting Diode Arrays Achieved by Direct Epitaxy

Esendag

Bai

Fletcher

et al. 2021

Physica Status Solidi (a)

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A systematic study has been conducted on a series of InGaN‐based micro‐light‐emitting diode (μLED) array samples which are achieved using the direct epitaxy overgrown approach on patterned templates by metalorganic chemical vapor deposition technique, where the diameters of the μLEDs are 40, 5, and 3.6 μm, respectively. The selective epitaxy approach allows to circumvent the major limitations of conventional fabrication methods of μLEDs which unavoidably introduce dry‐etching‐induced damages. Electrical characterizations are performed on the selective epitaxy overgrown μLEDs as well as conventional μLEDs fabricated using a standard dry‐etching method. For the overgrown μLEDs, the leakage current per μLED is smaller than those of the conventionally mesa‐etched μLEDs. It is worth highlighting that the single 3.6 μm μLED exhibits as low as a leakage current of 14.1 nA at a bias of −5 V. Moreover, in terms of leakage current density, the overgrown μLEDs exhibit much smaller and more consistent leakage than their mesa‐etched counterparts. Operational voltage RC constants also show more favorable to the overgrown devices than the conventionally mesa‐etched μLEDs.

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Near‐Complete Elimination of Size‐Dependent Efficiency Decrease in GaN Micro‐Light‐Emitting Diodes

Cited by 43 publications

References 23 publications

Micro‐Light‐Emitting Diodes Based on InGaN Materials with Quantum Dots

Micro‐Light‐Emitting Diodes Based on InGaN Materials with Quantum Dots

Role of Intrinsic Surface States in Efficiency Attenuation of GaN‐Based Micro‐Light‐Emitting‐Diodes

Investigation of Electrical Properties of InGaN‐Based Micro‐Light‐Emitting Diode Arrays Achieved by Direct Epitaxy

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