Analysis of GAA Junction Less NS FET Towards Analog and RF Applications at 30 nm Regime

IF 1.8 Q3 MATERIALS SCIENCE, MULTIDISCIPLINARY
Asisa Kumar Panigrahy;Sudheer Hanumanthakari;Shridhar B. Devamane;Shruti Bhargava Choubey;M. Prasad;D. Somasundaram;N. Kumareshan;N. Arun Vignesh;Gnanasaravanan Subramaniam;Durga Prakash M;Raghunandan Swain
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Abstract

This research focuses on a quantum model created using an entirely novel nanosheet FET. The standard model describes the performance of a Gate-all-around (GAA) Junction-less (JL) nanosheet device with a gate dielectric of SiO 2 and HfO 2 , each having a thickness of 1 nm. The performance of both the classical and quantum models of the GAA nanosheet device is evaluated using the visual TCAD tool, which measures the ION , IOFF , ION/ IOFF , threshold voltage, DIBL, gain parameters (g m , g d , A v ), gate capacitance, and cut-off frequency ( fT ). The device is suited for applications needing rapid switching since it has a low gate capacitance of the order of 10 –18 , according to the simulation results. A transconductance (g m ) value of 21 µS and an impressive cut-off frequency of 9.03 GHz are displayed during device analysis. A detailed investigation has also been done into the P-type device response for the same device. Finally, the proposed GAA nanosheet device is used in the inverter model. The NSFET-based inverter, although having higher gate capacitance, has the shortest propagation latency.
分析 GAA 结较少的 NS FET 在 30 纳米工艺下的模拟和射频应用
这项研究的重点是利用一种全新的纳米片场效应晶体管创建量子模型。该标准模型描述了栅极介电质为二氧化硅和二氧化铪(厚度均为 1 纳米)的全栅(GAA)无结(JL)纳米片器件的性能。利用可视化 TCAD 工具评估了 GAA 纳米片器件的经典模型和量子模型的性能,测量了 ION、IOFF、ION/ IOFF、阈值电压、DIBL、增益参数(gm、gd、Av)、栅极电容和截止频率 (fT)。根据仿真结果,该器件的栅极电容较低,约为 10-18 左右,因此适合需要快速开关的应用。在器件分析过程中,显示出 21 µS 的跨导 (gm) 值和 9.03 GHz 的惊人截止频率。此外,还对同一器件的 P 型器件响应进行了详细研究。最后,在逆变器模型中使用了所提出的 GAA 纳米片器件。基于 NSFET 的逆变器虽然具有较高的栅极电容,但却具有最短的传播延迟。
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
CiteScore
3.90
自引率
17.60%
发文量
10
审稿时长
12 weeks
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