Analysis of practical scaling limits in nanoelectromechanical switches

V. Ranganathan, S. Rajgopal, M. Mehregany, S. Bhunia
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引用次数: 2

Abstract

The trend of miniaturization, along with modern microfabrication facilities, has led to the development of nanoelectromechanical systems (NEMS) switches for use in low power and harsh environment applications. Dimensional scaling is attractive to improve integration density and operating voltage of NEMS devices. However, its effect on switch performance, leakage and dynamic power as well as practical limits on dimensional scaling are not well studied. Existing work in this area models the scaling trend and device performance based on parameters like voltage and dimensions. Although, most of them do not consider the effects of some nanoscale phenomena (surface forces, tunneling current) and leakage currents at G and D (off-state leakage), which can greatly affect circuit performance. This paper reports modeling and analysis of scaling effects and practical limits of scaling in cantilever-structured NEMS switches considering effects at nanoscale dimensions. It also analyzes the effects from a circuit level perspective, which corresponds to the end application of these NEMS structures. The goal of this paper is to establish a working range of dimensions and parameters which could result in reliable operating NEMS devices that can be incorporated into circuits.
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纳米机电开关的实际标度限制分析
小型化的趋势,以及现代微加工设备,导致了用于低功耗和恶劣环境应用的纳米机电系统(NEMS)开关的发展。尺寸缩放对提高NEMS器件的集成密度和工作电压具有重要意义。然而,其对开关性能、漏损和动态功率的影响以及尺寸缩放的实际限制还没有得到很好的研究。该领域的现有工作基于电压和尺寸等参数对缩放趋势和器件性能进行建模。然而,它们大多没有考虑一些纳米级现象(表面力、隧道电流)和G和D处漏电流(非状态漏电流)的影响,这些现象会极大地影响电路的性能。本文报道了考虑纳米尺度效应的悬臂结构NEMS开关的缩放效应的建模和分析以及缩放的实际限制。本文还从电路级的角度分析了这些影响,这与这些NEMS结构的最终应用相对应。本文的目标是建立一个尺寸和参数的工作范围,这可以导致可靠的操作NEMS设备,可以纳入电路。
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