Oxygen Embrittlement of Copper Leads

IEEE Transactions on Parts, Hybrids, and Packaging Pub Date : 1977-06-01 DOI:10.1109/TPHP.1977.1135182

N. Panousis, B. Wonsiewicz, L. Condra

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引用次数: 7

Abstract

Electrolytic tough pitch copper (known as ETP, CDA110, or copper alloy no. 110) is a material used in the manufacture of external leads for hybrid integrated circuits. Cracking during the formation of 90° bends and the relatively poor cyclic fatigue behavior of this material are identified as due to embrittlement caused by second-phase oxide inclusions. Optical and SEM examinations of failures led to the following model for embrittlement. Under the applied loads, voids nucleate at the second-phase inclusions; continued loading causes the voids to grow and coalesce, resulting in a fracture. This model is consistent with the published literature. Cyclic fatigue behavior, i.e., the median number of cycles to failure (MCTF), was found to vary inversely with the oxygen concentration. Over the range 10-650 ppm oxygen (by weight), the fatigue results could be represented by [100/MCTF] = 0.0228 [ppm oxygen] + 8.32. For both CDA110 and oxygen-free copper (CDA102 or copper alloy no. 102) the MCTF was found to vary inversely with the percent of bond deformation over the 10-60-percent range. Therefore, all cyclic fatigue comparisons among the various CDA110 and CDA102 specimens were made at a common bond deformation, chosen to be 35 percent. Oxygen-free copper with ~10 ppm oxygen was found to have about twice the MCTF as CDA110 with ~400 ppm oxygen.

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铜引线的氧脆

电解韧距铜(称为ETP, CDA110，或铜合金号。110)是用于制造混合集成电路外部引线的材料。在90°弯曲形成过程中的开裂和这种材料相对较差的循环疲劳行为被认为是由于第二相氧化物夹杂物引起的脆化。失效的光学和扫描电镜检查得出以下脆化模型。在外加载荷作用下，孔隙在第二相夹杂物处成核;持续的载荷会导致空隙增大并合并，从而导致裂缝。该模型与已发表的文献一致。循环疲劳行为，即失效循环次数的中位数(MCTF)，被发现与氧浓度成反比。在10-650 ppm氧气(以重量计)范围内，疲劳结果可以表示为[100/MCTF] = 0.0228 [ppm氧气]+ 8.32。适用于CDA110和无氧铜(CDA102或铜合金no。102)发现MCTF在10- 60%范围内与粘结变形百分比成反比变化。因此，各种CDA110和CDA102试样之间的所有循环疲劳比较都是在共同的粘结变形下进行的，选择35%。发现含氧~10 ppm的无氧铜的MCTF约为含氧~400 ppm的CDA110的两倍。

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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IEEE Transactions on Parts, Hybrids, and Packaging

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