Ulrich Wulf, Amanda Teodora Preda, George Alexandru Nemnes
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引用次数: 0
摘要
我们研究了硅/二氧化硅材料体系中的场效应纳米晶体管器件,该器件基于两个平行传导通道之间的横向共振隧穿。在引入一个简单的分片线性电势模型后,我们用 R 矩阵方法计算了量子传输特性。在传输特性中,我们发现在零控制电压附近存在一个狭窄的共振隧道峰。这种窄共振隧穿峰允许我们用较小的控制电压来切换漏极电流,从而为低能耗应用开辟了道路。与之前在具有更大沟道长度的 III-V 材料系统中研究过的类似双电子层隧道晶体管相比,我们发现漏极电流中的共振隧道峰在室温下依然存在。我们采用 R 矩阵方法对平面系统进行有效近似,并将分析结果与完整的数值计算结果进行比较。这使我们对横向隧道传输的内部过程有了基本的了解。
Transport in a Two-Channel Nanotransistor Device with Lateral Resonant Tunneling.
We study field effect nanotransistor devices in the Si/SiO2 material system which are based on lateral resonant tunneling between two parallel conduction channels. After introducing a simple piecewise linear potential model, we calculate the quantum transport properties in the R-matrix approach. In the transfer characteristics, we find a narrow resonant tunneling peak around zero control voltage. Such a narrow resonant tunneling peak allows one to switch the drain current with small control voltages, thus opening the way to low-energy applications. In contrast to similar double electron layer tunneling transistors that have been studied previously in III-V material systems with much larger channel lengths, the resonant tunneling peak in the drain current is found to persist at room temperature. We employ the R-matrix method in an effective approximation for planar systems and compare the analytical results with full numerical calculations. This provides a basic understanding of the inner processes pertaining to lateral tunneling transport.
期刊介绍:
Micromachines (ISSN 2072-666X) is an international, peer-reviewed open access journal which provides an advanced forum for studies related to micro-scaled machines and micromachinery. It publishes reviews, regular research papers and short communications. Our aim is to encourage scientists to publish their experimental and theoretical results in as much detail as possible. There is no restriction on the length of the papers. The full experimental details must be provided so that the results can be reproduced.
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