The electrical characteristic and trapping effect of AlGaN/GaN HEMTs with Fe and Fe/C co-doped GaN buffer layer

缓冲器(光纤) 宽禁带半导体 兴奋剂 材料科学 俘获 图层(电子) 光电子学 纳米技术 电气工程 生态学 生物 工程类
作者
Xuan Su,Ling Yang,Meng Zhang,Qing Zhu,Wenze Gao,Wei Zhao,Qian Yu,Qingyuan Chang,Hao Lu,Chunzhou Shi,Bin Hou,Mei Wu,Sheng Wu,Gang Qiu,Xiaohua Ma,Yue Hao
出处
期刊:Applied Physics Letters [American Institute of Physics]
卷期号:125 (10) 被引量:2
标识
DOI:10.1063/5.0219265
摘要

In this work, the influence of the Fe and Fe/C co-doped buffer on the AlGaN/GaN HEMTs is systematically investigated and compared. Due to the pronounced Fe tail in the unintentionally doped layer of the Fe-doped buffer compared to the Fe/C co-doped buffer, and the utilization of a two-step C doping process in the Fe/C co-doped buffer, it results in effectively reducing leakage current and increasing breakdown voltage without sacrificing saturation current and peak transconductance. Meanwhile, the RF characteristics of the Fe/C co-doped buffer are also superior to the Fe-doped buffer. More importantly, Drain Transient Current measurements indicate that the current collapse in the Fe/C co-doped buffer is smaller than that in the Fe-doped buffer. Through simulation analysis, the reason was identified: In the near-channel region, the weaker Fe tail effect in Fe/C co-doped buffer leads to a lower acceptor trap ionization. When the concentration of C exceeds 1 × 1016 cm−3, the ionization of traps introduced by Fe is suppressed. Additionally, the two-step C impurity distribution in the Fe/C co-doped buffer design modulates the electric field and potential, reducing the effective range of the electric field and potential, thereby effectively reducing the trap effects. These results are highly meaningful for the design of high-power amplifier epitaxial structures.
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