A design of improved nanoscale U-Shaped TFET by energy band modification for high performance digital and analog/RF applications

IF 1.2 Q4 NANOSCIENCE & NANOTECHNOLOGY
Melisa Ebrahimnia, Seyed Ali Sedigh Ziabari, Azadeh Kiani-sarkaleh
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引用次数: 0

Abstract

In this study, a new nanoscale U-shaped tunnel field-effect transistor (US TFET) structure is proposed. In order to start the design process, the drain region of the conventional US TFET is divided into two distinct parts with N+ and N- doping which is named the drain doping engineering (DDE). It is considered that the tunneling barrier at the channel-drain junction is increased and consequently the ambipolar current is decreased considerably. To continue the design process, the dual work function (DW) in the DDE-US TFET has been used to ameliorate the DC characteristics and the cutoff frequency. Moreover, we have used the metal implant (MI) in the source-side oxide of DDE-DW-US TFET as a technique to improve the device for high-frequency and low-power applications. The 2-D TCAD simulation results not only indicate the superiority of the proposed structure (DDE-DW-MI-US TFET) compared to others in terms of the high-frequency performance, but also illustrate the improvement of the DC parameters. Finally, the proposed device has been investigated by increasing the length of implanted metal in the source-side oxide. It is found that selecting the appropriate length contributes significantly to improve high-frequency performance.
一种用于高性能数字和模拟/射频应用的改进的纳米u型TFET的能带修饰设计
本研究提出了一种新型的纳米u型隧道场效应晶体管(US TFET)结构。为了启动设计过程,将传统的US TFET的漏极区分为N+和N-掺杂两个不同的部分,称为漏极掺杂工程(DDE)。考虑到通道-漏极结处的隧穿势垒增加,双极电流显著减小。为了继续设计过程,在DDE-US TFET中使用了双功函数(DW)来改善直流特性和截止频率。此外,我们在DDE-DW-US TFET的源侧氧化物中使用金属植入物(MI)作为改进器件高频和低功耗应用的技术。二维TCAD仿真结果不仅表明了所提出的结构(DDE-DW-MI-US TFET)在高频性能方面的优越性,而且说明了直流参数的改进。最后,通过增加源侧氧化物中植入金属的长度来研究该装置。研究发现,选择合适的长度对提高高频性能有显著作用。
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
international journal of nano dimension
international journal of nano dimension NANOSCIENCE & NANOTECHNOLOGY-
CiteScore
2.80
自引率
20.00%
发文量
0
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