Bouncing dynamics of electrostatically actuated NEM switches

Nano Express Pub Date : 2021-12-24 DOI:10.1088/2632-959X/ac4668

Mohamed Bognash, S. Asokanthan

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Abstract

The aim of the present research is to understand the bouncing dynamic behavior of nanoelectromechanical (NEM) switches in order to improve switch performance and reliability. It is well known that bouncing can dramatically degrade the switch performance and life; hence, in the present study, the bouncing dynamics of a cantilever-based NEM switch has been studied in detail. To this end, the repulsive van der Waals force is incorporated into a nano-switch model to capture the contact dynamics. Intermolecular forces, surface effects, and gas rarefication effects were also included in the proposed model. The Euler–Bernoulli beam theory and an approximate approach based on Galerkin’s method have been employed to predict transient dynamic responses. In the present study, performance parameters such as initial contact time, permanent contact time, major bounce height, and the number of bounces, were quantified in the presence of interactive system nonlinearities. The performance parameters were used to investigate the influence of surface effects and rarefication effects on the performance of an electrostatically actuated switch. Recommended operating conditions are suggested to avoid excessive bouncing for these types of NEM switches.

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静电驱动NEM开关的弹跳动力学

本研究的目的是了解纳米机电开关的弹跳动态行为，以提高开关的性能和可靠性。众所周知，弹跳会大大降低开关的性能和寿命;因此，在本研究中，详细研究了基于悬臂梁的NEM开关的弹跳动力学。为此，将排斥性范德华力纳入纳米开关模型以捕获接触动力学。分子间力、表面效应和气体稀薄效应也被包括在模型中。采用欧拉-伯努利梁理论和基于伽辽金方法的近似方法预测了瞬态动力响应。在本研究中，在存在交互系统非线性的情况下，对初始接触时间、永久接触时间、主弹跳高度和弹跳次数等性能参数进行了量化。利用性能参数研究了表面效应和稀薄效应对静电驱动开关性能的影响。建议的操作条件，以避免过度反弹的这些类型的NEM开关。

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

Nano Express

CiteScore

6.40

自引率

0.00%

发文量