多芬-肖特基势垒 FinFET 的温度变化：模拟/射频线性度研究

IF 2.9 4区工程技术 Q1 MULTIDISCIPLINARY SCIENCES

Advanced Theory and Simulations Pub Date : 2024-10-10 DOI:10.1002/adts.202400531

V Shalini, Prashanth Kumar

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引用次数: 0

摘要

本论文提出了一种基于氮化镓（GaN）的 FinFET 结构，并设计和模拟了一种多通道器件。本文使用 3D-Sentaures TCAD 仿真器研究了多鳍-肖特基势垒 FinFET 在 100-400 K 不同温度下的模拟/射频性能和线性度。对所提出的器件进行了温度分析，其中的关键参数包括漏极电流、ION/IOFF 比、跨电导 (gm)、高阶项 (gm2 和 gm3)、增益带宽积 (GBP)、截止频率 (fT) 和传输时间 (τ)、此外，还对跨导生成因子 (TGF)、跨导频率积 (TFP)、电压输入截点 (VIP2、VIP3)、输入截点 (IIP3) 和三阶互调失真 (IMD3) 进行了全面检查。因此，所提出的基于氮化镓的 FinFET 是基于氮化镓的模拟/射频应用的有力竞争者。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

Temperature-Induced Changes in Multifin-Schottky Barrier FinFETs: An Analog/RF Linearity Investigation

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Temperature-Induced Changes in Multifin-Schottky Barrier FinFETs: An Analog/RF Linearity Investigation

In this script, a Gallium Nitride (GaN)-based FinFET structure is proposed with a multi-channel device that is designed and simulated. Here, the 3D-Sentaures TCAD simulator is used to investigate the analog/radio frequency performance and linearity of the MultiFin-Schottky Barrier FinFET with different temperatures of 100–400 K. The proposed device underwent a temperature analysis, where critical parameters include drain current, I_ON/I_OFF ratio, Transconductance (g_m), higher-order terms (g_m2 and g_m3), Gain Bandwidth Product (GBP), Cut-off Frequency (f_T), Transit Time (τ), Transconductance Generation Factor (TGF), Transconductance Frequency Product (TFP), Voltage Input Intercept Point (VIP₂, VIP₃), Input Intercept Point (IIP₃), and Third Order Intermodulation Distortion (IMD₃) is thoroughly examined. Thus, the proposed GaN-based FinFET validates as a strong potential contender for GaN-based analog/RF applications.

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来源期刊

Advanced Theory and Simulations Multidisciplinary-Multidisciplinary

CiteScore

5.50

自引率

3.00%

发文量

221

期刊介绍： Advanced Theory and Simulations is an interdisciplinary, international, English-language journal that publishes high-quality scientific results focusing on the development and application of theoretical methods, modeling and simulation approaches in all natural science and medicine areas, including: materials, chemistry, condensed matter physics engineering, energy life science, biology, medicine atmospheric/environmental science, climate science planetary science, astronomy, cosmology method development, numerical methods, statistics