Enhancing P-type Conductivity in Mg-doped GaN Using Oxygen and Nitrogen Plasma Activation
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概要
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Plasma-assisted activation (PAA) has been studied in detail to enhance the electrical and optical performance of Mg-doped GaN surface layers. The plasma-assisted activation technique was carried out in a plasma-enhanced chemical vapor deposition (PECVD) system with various ratios of N2 to O2 environments at 400 and 640°C. Plasma energy in our studies was used to decompose the Mg–H complex, and H atoms were absorbed by O2 gas to form H2O. On the other hand, N2 gas was introduced to compensate for nitrogen vacancies. A hole concentration higher than $2.44\times 10^{17}$ cm-3 was determined near the GaN surface and a specific contact resistance of $8.6\times 10^{-5}$ $\Omega$$\cdot$cm2 was achieved, this is better than that of conventional 700°C thermal annealing. A 400°C PAA sample exhibits the same specific contact resistance of $2.1\times 10^{-4}$ $\Omega$$\cdot$cm2 as that of a 700°C thermal annealed sample. Moreover, room temperature-photoluminescence (RT-PL) showed that the 400 and 640°C PAA samples had a stronger intensity compared to that of conventional samples. Peak intensities of RT-PL were centered at 438 nm for all samples. The best electrical and optical properties appeared at a N2 to O2 ratio of $5:3$ in our study. A possible explanation is that a self-compensation mechanism is dominant in our plasma-assisted activation.
- Published by the Japan Society of Applied Physics through the Institute of Pure and Applied Physicsの論文
- 2005-04-15
著者
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Hwang Jun-dar
Department Of Electrical Engineering Da-yeh University
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Hwang Jun-dar
Department Of Electrical Engineerine Da-yeh University
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Chang Shoou-jinn
Department Of Electrical Engineering National Cheng Kung University
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Wu Ching-yuan
Department Of Electrical Engineering Da-yeh University
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Lai Zhca-Yong
Department of Electrical Engineering, Da-Yeh University, 112 Shan-Jiau Rd, Da-Tsuen, Changhua, Taiwa
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Lai Zhca-yong
Department Of Electrical Engineering Da-yeh University
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Lai Zhca-Young
Department of Electrical Engineering, Da-Yeh University
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