Proton-irradiation-induced degradation in GaN-based UV LEDs: Role of unintentionally doped carbon

Wang, Yingzhe; Zheng, Xuefeng; Zhu, Tian; Yue, Shaozhong; Pan, Ailing; Xu, Shengrui; Li, Peixian; Ma, Xiaohua; Zhang, Jincheng; Guo, Lixin; Hao, Yue

doi:10.1063/5.0133958

Applied Physics Letters

2023

DOI: 10.1063/5.0133958

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Proton-irradiation-induced degradation in GaN-based UV LEDs: Role of unintentionally doped carbon

Yingzhe Wang

Xuefeng Zheng

Tian Zhu

et al.

Abstract: Degradation and defect evolution in GaN-based UV LEDs under 3 MeV proton irradiation were throughly investigated in this work. Combined with the yellow luminescence band at ∼2.2 eV in photoluminescence spectra with the energy level of Ev + 0.16 eV extracted by deep-level transient spectroscopy measurement, an intrinsic CN-related defect with an abnormally decreased concentration after irradiation was identified. Based on energy levels, the spatial configuration of defects, and their correlations, several possi… Show more

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Cited by 3 publications

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UV/DUV light emitters

Khan,

Kneissl,

Amano

2023

Applied Physics Letters

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UV/DUV light emitters

Khan,

Kneissl,

Amano

2023

Applied Physics Letters

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Point defect effects in AlGaN 270-nm light emitting diodes introduced by MeV electron and proton irradiation

Polyakov,

Alexanyan,

Schemerov

et al. 2024

APL Materials

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Point defects were controllably introduced into 270 nm AlGaN Light-Emitting Diodes (LEDs) by 5 MeV electron and 1.1 MeV proton irradiations to examine the effect on electrical and luminescent characteristics. The 5 MeV electron irradiations had only a marginal effect on the charge distribution, current flow, and electroluminescence of LEDs for electron fluences up to 4.5 × 1016 e/cm2 that cause very strong degradation in green, blue, and near-UV LEDs. This lack of changes is attributed to the much higher charge densities in quantum-wells (QWs) and quantum barriers (QBs) of the 270 nm LEDs and to higher bond strength in high Al mole fraction AlGaN layers. By contrast, irradiation with 1.1 MeV protons with a fluence of 1016 p/cm2 leads to more than two orders of magnitude decrease in charge density in the QWs and QBs, a strong increase in the series resistance, and the emergence of deep electron traps near Ec-0.5 eV. The difference is explained by a much higher density of primary defects produced by protons. The observed effects are compared to changes in performance caused by aging after high driving current.

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Simulation of displacement damage induced by protons incident on AlxGa1–xN materials

He,

Bai,

Tian

et al. 2024

Acta Phys. Sin.

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Due to its excellent electrical properties and irradiation resistance, Gallium Nitride material, in combination with AlxGa1-xN materials of different contents, are expected to be used in future space electronics systems. However, most of their displacement damage studies are currently focused on GaN materials, and less on AlxGa1-xN materials. The displacement damage mechanism of protons from 10 keV to 300 MeV in AlxGa1-xN materials with different Al element contents is investigated by binary collision approximation method. The results show that the non-ionization energy loss of AlxGa1-xN material is found to decrease with the increment of proton energy. When the proton energy is lower than 40 MeV, the non-ionization energy loss becomes larger with the increase of Al content, while the trend is reversed when the proton energy is increased. Analyzing the primary knock-on atoms and non-ionizing energy deposition caused by protons, it is found that the primary knock-on atoms spectra of different AlxGa1-xN materials are similar, but the higher the content of Al, the higher the proportion of the self pri- mary knock-on atoms generated by elastic collisions. For the non-ionizing energy deposition produced by protons at different depth, the energy deposition due to elastic collisions is largest at the end of the trajectory, while the energy deposition due to inelastic collisions is uniformly distributed at the front of the trajectory but decreases at the end of the trajectory. This study provides a good insight for the application of GaN materials and devices in space radiation environment.

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Proton-irradiation-induced degradation in GaN-based UV LEDs: Role of unintentionally doped carbon

Cited by 3 publications

References 57 publications

UV/DUV light emitters

UV/DUV light emitters

Point defect effects in AlGaN 270-nm light emitting diodes introduced by MeV electron and proton irradiation

Simulation of displacement damage induced by protons incident on Al<sub><i>x</i></sub>Ga<sub>1<i>–x</i></sub>N materials

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