氮化镓圆柱肖特基势垒MOSFET(GaN-CSB-MOSFET)高频实现

2021 International Conference on Industrial Electronics Research and Applications (ICIERA) Pub Date : 2021-12-22 DOI:10.1109/ICIERA53202.2021.9726743

Swati Sharma, Anubha Goel, Sonam Rewari, V. Nath, R. Gupta

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引用次数: 4

摘要

对以氧化铝(Al2O3)为栅极氧化物的氮化镓圆柱肖特基势垒MOSFET(GaN-CSB-MOSFET)进行了模拟和测试。基于氮化镓的系统具有更宽的带隙，良好的输运特性和高击穿场。所提出的器件显示最小亚阈值斜率(SS)为67 mV/dec和较低的阈值电压。参数$\mathrm{V}_{\text{ds}}、\ \mathrm{g}_{\mathrm{m}}、\ \mathrm{g}_{\mathrm{d}}、\ \mathrm{f}_{\mathrm{T}}、\ \mathrm{C}_{\text{GG}}$、UPG、MTPG和FTP在GaN-CSB-MOSFET中表现出比硅柱肖特基势阱(Si-CSB) MOSFET更好的效果。这些性能指标使GaN-CSB-MOSFET成为不断发展的低功耗应用(如物联网的传感器和射频)的有希望的竞争者。

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Gallium Nitride Cylindrical Schottky Barrier MOSFET(GaN-CSB-MOSFET) For High-Frequency Implementation

Gallium Nitride Cylindrical Schottky Barrier MOSFET(GaN-CSB-MOSFET) using Aluminium Oxide (Al2O3) as gate oxide have been simulated and examined. The GaN-based system offers wider bandgaps, good transport properties, and a high breakdown field. The proposed devices display a minimum subthreshold slope (SS) of 67 mV/dec and a lower threshold voltage. Parameters like $\mathrm{V}_{\text{ds}},\ \mathrm{g}_{\mathrm{m}},\ \mathrm{g}_{\mathrm{d}},\ \mathrm{f}_{\mathrm{T}},\ \mathrm{C}_{\text{GG}}$, UPG, MTPG, and FTP show better results in GaN-CSB-MOSFET than Silicon Cylindrical Schottky barrier (Si-CSB) MOSFET. These performance metrics make GaN-CSB-MOSFET a promising contender for evolving low-power applications, such as sensors and RF for the Internet of Things.

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2021 International Conference on Industrial Electronics Research and Applications (ICIERA)

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