具有GaN帽层的1880 cm2 V-S In0.17 Al0.83N/GaN-on- si HEMTs的高电子迁移率

2020 IEEE Workshop on Wide Bandgap Power Devices and Applications in Asia (WiPDA Asia) Pub Date : 2020-09-23 DOI:10.1109/WiPDAAsia49671.2020.9360271

Y. Luo, I. Sanyal, W. Tzeng, Y. Ho, Ya-Chun Chang, Chih-Chao Hsu, J. Chyi, C. Wu

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引用次数: 0

摘要

由于近年来5G通信技术的发展，基于gan的hemt已经成为高速和高功率电子应用的非常有前途的候选者。由于GaN hemt与Si相比具有击穿电压、电子迁移率和电子浓度等固有特性，因此通过将GaN hemt引入mmic可以很容易地提高功率能力和开关速度。但对于传统的AlGaN/GaN HEMT，减少势垒$(t_{barrier})$的厚度以防止短通道效应将导致载流子浓度$(N_{s})$和迁移率[2]等电性能下降。因此，在这项工作中，我们用in $_{0.17}Al_{0.83}$N代替AlGaN，它可以在不降低Ns的情况下缩放到10nm以下。此外，还研究了生长薄氮化镓帽层以防止屏障氧化和制造t形栅极以改善高频特性

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High Electron Mobility of 1880 cm2 V-S In0.17 Al0.83N/GaN-on-Si HEMTs with GaN Cap Layer

Since the communication techniques for 5G developed recent years, GaN-based HEMTs have been very promising candidates for high-speed and high-power electronic applications. Due to the intrinsic properties such as breakdown voltage, electron mobility and electron concentration compared to Si, power capability and switching speed can be improved easily by introducing GaN HEMTs into MMICs. But for conventional AlGaN/GaN HEMT, reducing the thickness of barrier $(t_{barrier})$ to prevent short channel effect will cause electric properties degrade [1], such as carrier concentration $(N_{s})$ and mobility [2]. Therefore, in this work, we replace AlGaN with In$_{0.17}Al_{0.83}$N, which can be scaled below to 10nm without decreasing Ns. Also, growing a thin GaN cap layer to prevent barrier from oxidation and fabricating T-shaped gate to improving high frequency characteristics are done

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来源期刊

2020 IEEE Workshop on Wide Bandgap Power Devices and Applications in Asia (WiPDA Asia)

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