A balancing method for low Ron and high Vth normally-off GaN MISFET by preserving a damage-free thin AlGaN barrier layer

2018 IEEE 30th International Symposium on Power Semiconductor Devices and ICs (ISPSD) Pub Date : 2018-05-01 DOI:10.1109/ISPSD.2018.8393643

Jialin Zhang, Liang He, Liuan Li, Y. Ni, Taotao Que, Zhenxing Liu, Wenjing Wang, Jiexin Zheng, Yanfen Huang, J. Chen, Xin Gu, Yawen Zhao, Lei He, Zhisheng Wu, Yang Liu

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引用次数: 2

Abstract

Partially AlGaN recessed scheme based on selective area growth was experimentally demonstrated to improve the performance of normally-off GaN MISFET. The damage-free thin AlGaN barrier layer with lower Al-content in recessed region contributes to a positive Vth shift compared with the reference one (from 1.8 V to 2.5 V). At the same time this method realizes a high peak μκΣ of 2033 cm2/V·s and a low gate channel sheet resistance of 519 Ω/□ (@Vg = 12 V), which is a significant improvement compared with the fully recessed-gate device. The higher Al-contents AlGaN barrier layer regrown in accessed region is adopted to maintain high-conductivity 2DEG transport property. As a result, a maximum drain current of 645 mA/mm and a low on-resistance of 6.8 Ω-mni are obtained. The GaN MISFET also exhibits a low hysteresis, low gate leakage and slight current collapse. This technique could fabricate very promising normally-off GaN devices by designing thickness and Al-content of the controllable-growth thin AlGaN barrier layer.

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一种通过保留无损伤的薄AlGaN势垒层来平衡低Ron和高Vth正常关断GaN MISFET的方法

实验证明了基于选择性面积生长的部分AlGaN嵌入方案可以提高正常关闭GaN MISFET的性能。与参考器件相比，凹区al含量较低且无损伤的AlGaN薄势垒层的Vth位移为正(从1.8 V到2.5 V)，同时该方法实现了2033 cm2/V·s的峰值μκΣ和519 Ω/□(@Vg = 12 V)的低栅极沟道片电阻，与全凹栅器件相比有了显著提高。采用高al含量的AlGaN势垒层再生通路区域，以保持高电导率2DEG输运性能。因此，获得了645 mA/mm的最大漏极电流和6.8 Ω-mni的低导通电阻。GaN MISFET还具有低迟滞、低漏极和轻微的电流崩溃。该技术可以通过设计可控制生长的薄AlGaN势垒层的厚度和al含量来制造非常有前途的正常关闭的GaN器件。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

2018 IEEE 30th International Symposium on Power Semiconductor Devices and ICs (ISPSD)

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