Realization of Highly Efficient InGaN Green LEDs with Sandwich-like Multiple Quantum Well Structure: Role of Enhanced Interwell Carrier Transport

Lv, Quanjiang; Liu, Junlin; Mo, Chunlan; Zhang, Jianli; Wu, Xiaoming; Wu, Qingfeng; Jiang, Fengyi

doi:10.1021/acsphotonics.8b01040

Cited by 62 publications

(49 citation statements)

References 51 publications

(104 reference statements)

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“…The broadband light emitters can be constructed based on ternary compounds such as indium gallium nitride (InGaN) formed from III-V bulk semiconductors, which offer tunable band gaps from 3.4 eV (GaN) to 0.64 eV (InN) [4], [5]. However, a high In content required to generate red or near-infrared light decreases the efficiency of light generation due to In segregation and a higher defect density resulting from the lattice mismatch with the substrate [6]. These problems can be overcome by developing novel 2D-3D heterostructures based on GaN interfaced with transition metal dichalcogenides (TMDs) which have lattice constant similar to GaN [7].…”

Section: Introductionmentioning

confidence: 99%

Absorption and emission modulation in a MoS₂–GaN (0001) heterostructure by interface phonon–exciton coupling

Poudel¹,

Sławińska²,

Gopal³

et al. 2019

Photon. Res.

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______________________________________________________________________________________________________ Semiconductor heterostructures based on layered two-dimensional transition metal dichalcogenides (TMD) interfaced to gallium nitride (GaN) are excellent material systems to realize broadband light emitters and absorbers. The surface properties of the polar semiconductor, such as GaN are dominated by interface phonons, thus the optical properties of the vertical heterostructure depend strongly on the interface exciton-phonon coupling. The origin and activation of different Raman modes in the heterostructure due to coupling between interfacial phonons and optically generated carriers in a monolayer MoS2-GaN (0001) heterostructure was observed. This coupling strongly influences the nonequilibrium absorption properties of MoS2 and the emission properties of both semiconductors. Density functional theory (DFT) calculations were performed to study the band alignment of the interface, which revealed a type-I heterostructure. The optical excitation with interband transition in MoS2 at K-point strongly modulates the C excitonic band in MoS2. The overlap of absorption and emission bands of GaN with the absorption bands of MoS2 induces the energy and charge transfer across the interface with an optical excitation at Γ-point. A strong modulation of the excitonic absorption states is observed in MoS2 on GaN substrate with transient optical pump-probe spectroscopy. The interaction of carriers with phonons and defect states leads to the enhanced and blue shifted emission in MoS2 on GaN substrate. Our results demonstrate the relevance of interface coupling between phonons and carriers for the development of optical and electronic applications. ______________________________________________________________________________________________________

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Section: Introductionmentioning

confidence: 99%

Absorption and emission modulation in a MoS₂–GaN (0001) heterostructure by interface phonon–exciton coupling

Poudel¹,

Sławińska²,

Gopal³

et al. 2019

Photon. Res.

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“…Moreover, the AlN thin films prepared using the PVD sputtering without oxygen incorporation had a hexagonal wurtzite structure. A small peak of the γ-Al 2 O 3 (12)(13)(14)(15)(16)(17)(18)(19)(20)(21)(22)(23)(24)(25)(26)(27)(28)(29)(30)(31) plane was observed (yellow dotted line) when the O 2 flow rate was 1 sccm (Buffer B) [20]. With an increasing O2 flow rate, the diffraction peaks of AlN (0002) gradually merged with the small peak of γ-Al 2 O 3 (12-31) plane, indicating the infusion of oxygen in the AlN structure of the hexagonal system.…”

Section: A Alno Buffer Layersmentioning

confidence: 99%

“…Furthermore, the contrasting thermodynamic and structural properties of InN and GaN lead to low miscibility, making it difficult to grow highquality green-emitting InGaN/GaN multiple quantum wells (MQWs) [9]. Several methods have been used to improve the EQE of green LEDs, such as the use of pattern sapphire substrates, non-polar or semi-polar substrates [10], AlGaN ternary quantum well protective layers [11,12], sandwich MQW growth process [13,14], and controlling the strain, field, electronic band mechanism to reduce the influence of QCSE [15,16]. The EQE of the green LEDs has been improved to reach 40%.…”

Section: Introductionmentioning

confidence: 99%

High External Quantum Efficiency Green Light Emitting Diodes on Stress-Manipulated AlNO Buffer Layers

Wang

Chen²,

et al. 2022

IEEE Photonics J.

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We demonstrated high-brightness InGaN/GaN green light emitting diodes (LEDs) with ex-situ sputtered stressmanipulated AlNO buffer on 4-inch patterned sapphire substrates. The lattice constant of the AlNO buffer was adjusted by oxygen flow. As a result, the dislocation density and the in-plane compressive stress caused by lattice mismatch were greatly reduced, while the interface quality of the InGaN/GaN multiple quantum wells and the uniformity of the indium composition were greatly improved. At 20A/cm 2 , the external quantum efficiency and wall plug efficiency of the 526.4-nm-green LEDs grown on the sputtered AlNO buffer reached 46.1% and 41.9%, which were both higher than reported values.

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“…[ 1 ] The external quantum efficiencies (EQEs) of current blue, green, and yellow LEDs based on InGaN quantum well (QW) are as high as 80%, 50%, and 30%, respectively. [ 2–7 ] However, several bottlenecks exist in utilizing them for some emerging applications beyond lighting, such as micro‐LED display and high‐speed visible‐light communication (VLC). Over the past decade, micro‐LEDs with a chip size below 100 µm (especially below 50 µm) have attracted considerable attention as the most promising next‐generation display technology after LCD and organic LEDs (OLEDs).…”

Section: Introductionmentioning

confidence: 99%

Green InGaN Quantum Dots Breaking through Efficiency and Bandwidth Bottlenecks of Micro‐LEDs

Wang

Chen

et al. 2021

Laser & Photonics Reviews

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Micro‐LEDs are regarded as ideal light sources for next‐generation display and high‐speed visible‐light communication (VLC). However, the conventional micro‐LEDs based on InGaN quantum well (QW) active region suffer from a low efficiency under small injection (below 1 A cm−2) due to the size‐dependent effect and a limited 3 dB bandwidth (hundreds of MHz) due to quantum‐confined Stark effect. Here, InGaN quantum dots (QDs) are proposed as the active region of micro‐LEDs to address these challenges for their strong localization and low‐strain features. Green InGaN QDs are self‐assembled under Stranski–Krastanov (SK) and Volmer–Weber (VW) modes by using metal organic vapor phase epitaxy. The SK QDs can shift the peak efficiency of a micro‐LED to an extremely low current density of 0.5 A cm−2 (almost two orders of magnitude lower compared to QW ones) with an external quantum efficiency of 18.2% (nearly two times higher than present green micro‐LEDs). Besides, green micro‐LEDs based on VW QDs reach a 3 dB bandwidth of 1.3 GHz. These results indicate that InGaN QDs can provide an ultimate solution to micro‐LEDs for display and VLC applications, especially since they are fully compatible with current light‐emitting diode (LED) industrial technology.

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Realization of Highly Efficient InGaN Green LEDs with Sandwich-like Multiple Quantum Well Structure: Role of Enhanced Interwell Carrier Transport

Cited by 62 publications

References 51 publications

Absorption and emission modulation in a MoS₂–GaN (0001) heterostructure by interface phonon–exciton coupling

Absorption and emission modulation in a MoS₂–GaN (0001) heterostructure by interface phonon–exciton coupling

High External Quantum Efficiency Green Light Emitting Diodes on Stress-Manipulated AlNO Buffer Layers

Green InGaN Quantum Dots Breaking through Efficiency and Bandwidth Bottlenecks of Micro‐LEDs

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Realization of Highly Efficient InGaN Green LEDs with Sandwich-like Multiple Quantum Well Structure: Role of Enhanced Interwell Carrier Transport

Cited by 62 publications

References 51 publications

Absorption and emission modulation in a MoS2–GaN (0001) heterostructure by interface phonon–exciton coupling

Absorption and emission modulation in a MoS2–GaN (0001) heterostructure by interface phonon–exciton coupling

High External Quantum Efficiency Green Light Emitting Diodes on Stress-Manipulated AlNO Buffer Layers

Green InGaN Quantum Dots Breaking through Efficiency and Bandwidth Bottlenecks of Micro‐LEDs

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Absorption and emission modulation in a MoS₂–GaN (0001) heterostructure by interface phonon–exciton coupling

Absorption and emission modulation in a MoS₂–GaN (0001) heterostructure by interface phonon–exciton coupling