Degradation evaluation of microelectromechanical thermal actuators

SPIE MOEMS-MEMS Pub Date : 2008-02-07 DOI:10.1117/12.760918

J. K. Luo, Y. Q. Fu, Q. Huang, J. Williams, W. Milne

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Abstract

Metal based thermal microactuators normally have lower operation temperatures than those of Si-based ones; hence they have great potential for applications. However, metal-based thermal actuators easily suffer from degradation such as plastic deformation. In this study, planar thermal actuators were made by a single mask process using electroplated nickel as the active material, and their thermal degradation has been studied. Electrical tests show that the Ni-based thermal actuators deliver a maximum displacement of ~20 m at an average temperature of ~420 °C, much lower than that of Si-based microactuators. However, the displacement strongly depends on the frequency and peak voltage of the pulse applied. Back bending was clearly observed at a maximum temperature as low as 240 °C. Both forward and backward displacements increase with increasing the temperature up to ~450 °C, and then decreases with power. Scanning electron microscopy observation clearly showed that Ni structure deforms and reflows at power above 50mW. The compressive stress is believed to be responsible for Ni piling-up (creep), while the tensile stress upon removing the pulse current is responsible for necking at the hottest section of the device. Energy dispersive X-ray diffraction analysis revealed severe oxidation of the Ni-structure induced by Joule-heating of the current.

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微机电热致动器的退化评价

金属基热微执行器通常比硅基热微执行器具有更低的工作温度;因此，它们具有很大的应用潜力。然而，金属基热致动器容易遭受退化，如塑性变形。本研究以电镀镍为活性材料，采用单掩膜法制备平面热致动器，并对其热降解进行了研究。电学测试表明，在~420℃的平均温度下，ni基微致动器的最大位移为~20 m，远低于si基微致动器。然而，位移很大程度上取决于所施加脉冲的频率和峰值电压。在最高温度低至240°C时，可以清楚地观察到背部弯曲。在~450℃范围内，前后位移随温度升高而增大，随功率增大而减小。扫描电镜观察清楚地表明，在功率大于50mW时，Ni结构发生变形并回流。压应力被认为是导致Ni堆积(蠕变)的原因，而去除脉冲电流后的拉应力是导致器件最热部分颈缩的原因。能量色散x射线衍射分析表明，电流的焦耳加热导致ni结构严重氧化。

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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SPIE MOEMS-MEMS

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