Electrical failure and damage analysis of multi-layer metal films on flexible substrate during cyclic bending deformation

18th IEEE International Symposium on the Physical and Failure Analysis of Integrated Circuits (IPFA) Pub Date : 2011-07-04 DOI:10.1109/IPFA.2011.5992725

Byoung-Joon Kim, Hae-A-Seul Shin, I. Choi, Young‐Chang Joo

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引用次数: 14

Abstract

The electrical resistance Cu film on flexible substrate was investigated in cyclic bending deformation. The electrical resistance of 1 µm thick Cu film on flexible substrate increased up to 120 % after 500,000 cycles in 1.1 % tensile bending strain. Crack and extrusion were observed due to the fatigue damage of metal film. Low bending strain did not cause any damage on metal film but higher bending strain resulted in severe electrical and mechanical damage. Thinner film showed higher fatigue resistance because of the better mechanical property of thin film. Cu film with NiCr under-layer showed poorer fatigue resistance in tensile bending mode. Ni capping layer did not improve the fatigue resistance of Cu film, but Al capping layer suppressed crack formation and lowered electrical resistance change. The NiCr under layer, Ni capping layer, and Al capping layer effect on electrical resistance change of Cu film was compared with Cu only sample.

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柔性基板上多层金属薄膜在循环弯曲变形过程中的电气失效与损伤分析

研究了柔性基板上铜薄膜在循环弯曲变形中的电阻特性。在1.1%的拉伸弯曲应变下，在50万次循环后，1µm厚的Cu薄膜的电阻增加了120%。由于金属薄膜的疲劳损伤，出现了裂纹和挤压现象。低弯曲应变不会对金属膜造成损伤，而高弯曲应变会对金属膜造成严重的电损伤和机械损伤。由于薄膜的力学性能较好，薄膜具有较高的抗疲劳性能。在拉伸弯曲模式下，含有NiCr的Cu薄膜的抗疲劳性能较差。Ni包覆层没有提高Cu膜的抗疲劳性能，而Al包覆层抑制了裂纹的形成，降低了电阻的变化。比较了NiCr下层、Ni盖层和Al盖层对Cu膜电阻变化的影响。

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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18th IEEE International Symposium on the Physical and Failure Analysis of Integrated Circuits (IPFA)

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