The investigation of the electrical contact resistance through thin oxide layer on a nanometer scale

2016 IEEE 62nd Holm Conference on Electrical Contacts (Holm) Pub Date : 2016-10-01 DOI:10.1109/HOLM.2016.7780008

T. Yudate, J. Toyoizumi, M. Onuma, T. Kondo, T. Shimizu, S. Kawabata, N. Watanabe, K. Mori

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引用次数: 1

Abstract

Electrical connectors plated with tin are widely used in automobiles. Therefore, it is important to understand electrical conduction mechanism and contact structure of tin plating which is coated with thin oxide layer in order to realize small electrical connectors which are able to operate under low load force condition. Then we constructed nano-manipulator to be able to observe the mechanical contact, measure the load force and electrical resistance simultaneously in a scanning electron microscope. As a result, we found that the electrical resistance drastically reduces as the load force increases, and could observe that the tin penetrates into cracks in oxide layer and finally reaches on the surface. These results are the same as those of tin oxide layer fabricated by sputtering. Therefore, it is confirmed that the tin appearance on the contact surface is very important for electrical conduction even in the case of tin with natural oxide. For size miniaturization and load force reduction of tin plating connectors in near future, it is necessary to focus on the oxide layer fracturing and control the tin appearance on the contact interface.

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纳米尺度下薄氧化层接触电阻的研究

镀锡电连接器广泛应用于汽车上。因此，了解涂有薄氧化层的镀锡的导电机理和接触结构，对于实现能够在低负载力条件下工作的小型电连接器具有重要意义。在此基础上，构建了能够在扫描电子显微镜下同时观察机械接触、载荷力和电阻的纳米机械臂。结果，我们发现电阻随着载荷力的增加而急剧减小，并且可以观察到锡渗透到氧化层的裂纹中，最终到达表面。这些结果与溅射法制备氧化锡层的结果一致。因此，证实了接触表面锡的外观对于导电是非常重要的，即使是在天然氧化锡的情况下。为了在不久的将来实现镀锡连接器的尺寸小型化和载荷力降低，有必要重点关注氧化层的破裂和控制接触界面上的锡外观。

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2016 IEEE 62nd Holm Conference on Electrical Contacts (Holm)

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