NEMS谐振器中压力相关q因子的仿真与测量

2014 15th International Conference on Thermal, Mechanical and Mulit-Physics Simulation and Experiments in Microelectronics and Microsystems (EuroSimE) Pub Date : 2014-04-07 DOI:10.1109/EUROSIME.2014.6813858

J. Manz, G. Schrag, G. Wachutka

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引用次数: 0

摘要

从理论上和实验上确定了悬浮部分与衬底间隙为纳米级的各种机械谐振器的流体阻尼和由此产生的q因子。这些研究是在从大气压降至约3pa的压力范围内进行的。将[1,2]中提出的混合水平模型扩展到滑动流动和分子动力学模式，对器件可移动部分与衬底之间纳米间隙内的空气流动进行了建模。压力相关测量使用激光多普勒振动仪进行。在每一压力区，提取的Q因子与理论预测值非常吻合。这是一个值得注意的结果，因为即使在正常压力下，对于本工作中考虑的纳米特征尺寸，也达到了连续理论描述的有效性范围。

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Simulation and measurement of pressure dependent Q-factors in NEMS resonators

The fluidic damping and the hereof resulting Q-factor of various mechanical resonators with gaps of nanometer size between suspended part and substrate was theoretically and experimentally determined. These investigations have been carried out in the pressure regime from atmospheric pressure down to about 3 Pa. The air flow in the nanogap between the movable part of the device and the substrate was modeled by extending the mixed level model presented in [1, 2] to the slip flow and molecular dynamical regime. The pressure-dependent measurements were carried out using a Laser-Doppler vibrometer. The extracted Q factors conform very well with those expected from theory in every pressure regime. This is a noticeable result, because even at normal pressure the range of validity for a continuum-theoretical description is reached for the nanometer feature sizes considered in this work.

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2014 15th International Conference on Thermal, Mechanical and Mulit-Physics Simulation and Experiments in Microelectronics and Microsystems (EuroSimE)

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