Nanostructure analysis of InGaN/GaN quantum wells based on semi-polar-faced GaN nanorods

Huang, Yu‐Sheng; Feng, Shih‐Wei; Weng, Yu-Hsin; Chen, Yung‐Sheng; Kuo, Chie‐Tong; Lu, Ming-Yen; Cheng, Yung‐Chen; Hsieh, Ya‐Ping; Wang, Hsiang‐Chen

doi:10.1364/ome.7.000320

Cited by 6 publications

(2 citation statements)

References 41 publications

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“…Realizing high-performance GaN-based devices requires metal/GaN interface with a minimum interface state density, which can act as electron traps or limit to modulate the barrier heights according to metal work function by pinning the Fermi level [ 5 , 6 ]. For other GaN-based device improvement techniques, some methods such as coalescence overgrowth of GaN nanocolumns, nonpolar m -plane GaN, nanoimprint GaN template, and semi-polar face GaN nanorods have also been demonstrated [ 7 – 11 ]. Among III-nitride compound semiconductors, aluminum nitride (AlN) can be applied to UV detectors, short-wavelength emitters and detectors, due to its high bandgap (∼ 6.2 eV), high thermal conductivity, high electric resistance, as well as low expansion at high temperatures [ 12 , 13 ].…”

Section: Introductionmentioning

confidence: 99%

Thickness Dependence on Interfacial and Electrical Properties in Atomic Layer Deposited AlN on c-plane GaN

2018

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The interfacial and electrical properties of atomic layer deposited AlN on n-GaN with different AlN thicknesses were investigated. According to capacitance–voltage (C–V) characteristics, the sample with a 7.4-nm-thick AlN showed the highest interface and oxide trap densities. When the AlN thickness was 0.7 nm, X-ray photoelectron spectroscopy (XPS) spectra showed the dominant peak associated with Al–O bonds, along with no clear AlN peak. The amount of remained oxygen atoms near the GaN surface was found to decrease for the thicker AlN. However, many oxygen atoms were present across the AlN layer, provided the oxygen-related defects, which eventually increased the interface state density. The barrier inhomogeneity with thermionic emission (TE) model was appropriate to explain the forward bias current for the sample with a 7.4-nm-thick AlN, which was not proper for the sample with a 0.7-nm-thick AlN. The reverse leakage currents for both the samples with 0.7- and 7.4-nm-thick AlN were explained better using Fowler–Nordheim (FN) rather than Poole–Frenkel emissions.

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Section: Introductionmentioning

confidence: 99%

Thickness Dependence on Interfacial and Electrical Properties in Atomic Layer Deposited AlN on c-plane GaN

2018

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“…Auger recombination [ 14 , 15 ] and carrier delocalization from indium-rich regions to dislocations [ 16 ] have also been proposed. The growth of III-nitrides along the nonpolar m - and a -axes [ 11 , 17 , 18 ], semipolar axis [ 19 ], and - c -axis ( nitrogen -polar) [ 20 ] can overcome polarization effects. Without polarization effects in a nonpolar m -plane LED ( m -LED), more uniform hole distribution among the wells and suppressed electron overflow out of the electron blocking layer can significantly reduce the electron leakage current and efficiency droop [ 11 ].…”

Section: Introductionmentioning

confidence: 99%

Efficient Carrier Injection, Transport, Relaxation, and Recombination Associated with a Stronger Carrier Localization and a Low Polarization Effect of Nonpolar m-plane InGaN/GaN Light-Emitting Diodes

2017

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Based on time-resolved electroluminescence (TREL) measurement, more efficient carrier injection, transport, relaxation, and recombination associated with a stronger carrier localization and a low polarization effect in a nonpolar m-plane InGaN/GaN light emitting diode (m-LED), compared with those in a polar c-LED, are reported. With a higher applied voltage in the c-LED, decreasing response time and rising time improve device performance, but a longer recombination time degrades luminescence efficiency. By using an m-LED with a stronger carrier localization and a low polarization effect, shorter response, rising, and recombination times provide more efficient carrier injection, transport, relaxation, and recombination. These advantages can be realized for high-power and high-speed flash LEDs. In addition, with a weaker carrier localization and a polarization effect in the c-LED, the slower radiative and faster nonradiative decay rates at a larger applied voltage result in the slower total decay rate and the lower luminescence efficiency. For the m-LED at a higher applied voltage, a slow decreasing nonradiative decay rate is beneficial to device performance, while the more slowly decreasing and overall faster radiative decay rate of the m-LED than that of the c-LED demonstrates that a stronger carrier localization and a reduced polarization effect are efficient for carrier recombination. The resulting recombination dynamics are correlated with the device characteristics and performance of the c- and m-LEDs.

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Enhanced luminescence property of InGaN/GaN nanorod array light emitting diode

Xu¹,

Han

2019

Opt. Eng.

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Nanostructure analysis of InGaN/GaN quantum wells based on semi-polar-faced GaN nanorods

Cited by 6 publications

References 41 publications

Thickness Dependence on Interfacial and Electrical Properties in Atomic Layer Deposited AlN on c-plane GaN

Thickness Dependence on Interfacial and Electrical Properties in Atomic Layer Deposited AlN on c-plane GaN

Efficient Carrier Injection, Transport, Relaxation, and Recombination Associated with a Stronger Carrier Localization and a Low Polarization Effect of Nonpolar m-plane InGaN/GaN Light-Emitting Diodes

Enhanced luminescence property of InGaN/GaN nanorod array light emitting diode

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