悬臂梁
电容感应
材料科学
微电子机械系统
结构稳定性
加速度计
理论(学习稳定性)
振动
纳米技术
结构工程
声学
复合材料
计算机科学
工程类
电气工程
物理
机器学习
操作系统
作者
Ryosuke Miyai,Tomoyuki Kurioka,Chun‐Yi Chen,Tso‐Fu Mark Chang,Akira Onishi,Parthojit Chakraborty,Katsuyuki Machida,Hiroyuki Ito,Yoshihiro Miyake,Masato Sone
标识
DOI:10.1016/j.mne.2024.100244
摘要
A Gold micro-electro-mechanical-systems (Au-MEMS) capacitive accelerometer having Ti/Au multi-layered structures is a promising device to detect very weak accelerations, such as muscle sounds, because of the high mass density of Au. However, Au is a soft metal, which raises concerns about the structural stability of the Au-MEMS capacitive accelerometers for practical use. In this work, we clarify the key geometric parameters to enhance their long-term structural stability by conducting a long-term vibration test for a total of 240 Ti/Au multi-layered micro-cantilevers with different geometric parameters, such as the length, width, and thickness of the micro-cantilevers, and the number of Ti/Au multi-layered structures. The long-term structural stability is evaluated from the change in the tip height of the micro-cantilevers before and after the vibration tests. These tests demonstrate that the micro-cantilevers with a shorter length, larger thickness, and more Ti/Au multi-layered structures are found to show better long-term structural stability.
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