E-mode p-channel GaN/AlGaN HFETs with κ-Ga2O3 as gate oxide

IF 3.3 3区工程技术 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC

Optical and Quantum Electronics Pub Date : 2025-04-20 DOI:10.1007/s11082-025-08214-z

Wenchao Ma, Wei Wang, Jin Wang, Rui Wang, Ting Zhi, Irina N. Parkhomenko, Fadei F. Komarov, Dunjun Chen, Rong Zhang, Junjun Xue

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Abstract

In this article, a κ-Ga₂O₃ cap layer is introduced as gate dielectric to achieve E-mode GaN p-channel heterostructure FETs (p-HFETs). Due to the high spontaneous polarization of κ-Ga₂O₃, 2DEG that up to 1.51 × 10¹⁴ cm^− 2 are induced at the κ-Ga₂O₃/GaN interface. Based on device simulations, the threshold voltage (V_TH) can reach a high value of -2.42 V and maintain negative even when the thickness of the GaN channel (t_ch) is increased to 50 nm. By interconnecting base and gate to form a double-gate (DG) structure, the control of 2DEG and 2DHG can be realized. The results show that p-HFETs with DG structure not only exhibit a threefold increase in the on-current (I_ON) while maintaining the E-mode operation, reaching 24.87 mA/mm with V_TH of -1.25 V, but also reduce the gate leakage current at forward bias. Furthermore, the utilization of κ-Ga₂O₃ as the gate dielectric results in an enhancement of the gate breakdown voltage to -35.8 V. The proposed DG p-HFETs represent a promising approach to achieving high-performance enhancement mode p-channel GaN devices.

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以κ-Ga2O3为栅极氧化物的e模p沟道GaN/AlGaN hfet

本文采用κ-Ga2O3帽层作为栅极介质，实现了e型GaN p沟道异质结构场效应管（p- hfet）。由于κ-Ga2O3的高自发极化，在κ-Ga2O3/GaN界面处产生了高达1.51 × 1014 cm−2的2DEG。基于器件仿真，当GaN通道（tch）厚度增加到50 nm时，阈值电压（VTH）可以达到-2.42 V的高值并保持为负值。通过基极和栅极互连形成双栅极（DG）结构，可以实现对2DEG和2DHG的控制。结果表明，DG结构的p- hfet在保持e模工作的同时，导通电流（ION）增加了三倍，在VTH为-1.25 V时达到24.87 mA/mm，并且减小了正偏置栅漏电流。此外，利用κ-Ga2O3作为栅极介质，栅极击穿电压提高到-35.8 V。所提出的DG p- hfet代表了实现高性能增强模式p通道GaN器件的有前途的方法。

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

Optical and Quantum Electronics 工程技术-工程：电子与电气

CiteScore

4.60

自引率

20.00%

发文量

810

审稿时长

3.8 months

期刊介绍： Optical and Quantum Electronics provides an international forum for the publication of original research papers, tutorial reviews and letters in such fields as optical physics, optical engineering and optoelectronics. Special issues are published on topics of current interest. Optical and Quantum Electronics is published monthly. It is concerned with the technology and physics of optical systems, components and devices, i.e., with topics such as: optical fibres; semiconductor lasers and LEDs; light detection and imaging devices; nanophotonics; photonic integration and optoelectronic integrated circuits; silicon photonics; displays; optical communications from devices to systems; materials for photonics (e.g. semiconductors, glasses, graphene); the physics and simulation of optical devices and systems; nanotechnologies in photonics (including engineered nano-structures such as photonic crystals, sub-wavelength photonic structures, metamaterials, and plasmonics); advanced quantum and optoelectronic applications (e.g. quantum computing, memory and communications, quantum sensing and quantum dots); photonic sensors and bio-sensors; Terahertz phenomena; non-linear optics and ultrafast phenomena; green photonics.