n沟道单层黑磷纳米带晶体管的直流和射频性能

Q4 Engineering
K. Alam
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引用次数: 0

摘要

二维黑磷是一个相对较新的发现。关于黑磷二维晶体管的研究主要集中在模拟和射频性能方面。然而,黑磷纳米带晶体管的射频性能还有待进一步研究。我们使用四波段紧密结合哈密顿量和非平衡格林函数量子输运模拟器来研究单层黑磷纳米带晶体管的直流和射频性能。我们发现在关闭状态下,电子带内隧穿是电流流动的原因,而在打开状态下,电子流过通道势垒的顶部。该黑磷纳米带晶体管的VDD为0.4伏,栅极长度为5 nm,直流性能指标为510µa /µm导通电流,105开/关电流比和65 mV/dec逆亚阈值斜率。该器件的射频性能特征为:截止频率(单位电流增益)为772.84 GHz,最大振荡频率(单位功率增益)为1.15 THz,晶体管工作在导通状态下,开路电压增益为26.7 dB。器件的射频性能受到源极和漏极接触电阻的显著影响。源极和漏极电阻均为零时,截止频率增加到995.23 GHz,单位功率增益频率增加到4.16 THz。该设备在893 GHz以上显示无条件稳定,在此频率以下显示条件稳定。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
DC and RF Performance of an N-channel Monolayer Black Phosphorus Nanoribbon Transistor
Two-dimensional black phosphorus is a relatively new discovery. There are numerous studies on black phosphorus two-dimensional transistors that focus on analog and RF performance. However, the RF performance of black phosphorus nanoribbon transistors is yet to be explored. We use a four-band tight binding Hamiltonian in conjunction with a non-equilibrium Green's function quantum transport simulator to investigate both the DC and RF performance of a monolayer black phosphorus nanoribbon transistor. We found that electron intra-band tunneling is responsible for current flow in the off-state, while in the on-state, the electrons flow over the top of the channel barrier potential. With a VDD of 0.4 volt and a gate length of 5 nm, our black phosphorus nanoribbon transistor has DC performance metrics of 510 µA/µm on-state current, 105 on/off current ratio, and 65 mV/dec inverse subthreshold slope. The device's RF performance characteristics are as follows: cut-off (unity current gain) frequency of 772.84 GHz, maximum oscillation (unity power gain) frequency of 1.15 THz, and open circuit voltage gain of 26.7 dB with transistor operating in the on-state. The RF performance of the device is found to be significantly impacted by the source and drain contact resistances. With source and drain resistances set to zero, the cut-off frequency increases to 995.23 GHz and the unity power gain frequency increases to 4.16 THz. The device shows unconditional stability above 893 GHz and it is conditionally stable below this frequency. 
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来源期刊
Journal of Electrical and Electronics Engineering
Journal of Electrical and Electronics Engineering Engineering-Electrical and Electronic Engineering
CiteScore
0.90
自引率
0.00%
发文量
0
审稿时长
16 weeks
期刊介绍: Journal of Electrical and Electronics Engineering is a scientific interdisciplinary, application-oriented publication that offer to the researchers and to the PhD students the possibility to disseminate their novel and original scientific and research contributions in the field of electrical and electronics engineering. The articles are reviewed by professionals and the selection of the papers is based only on the quality of their content and following the next criteria: the papers presents the research results of the authors, the papers / the content of the papers have not been submitted or published elsewhere, the paper must be written in English, as well as the fact that the papers should include in the reference list papers already published in recent years in the Journal of Electrical and Electronics Engineering that present similar research results. The topics and instructions for authors of this journal can be found to the appropiate sections.
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