Black Mushroom Formation on Aluminum Bond Pad

International Symposium for Testing and Failure Analysis Pub Date : 2022-10-30 DOI:10.31399/asm.cp.istfa2022p0306

Yong Guo, Brian Smith, Yanan Guo, J. Hurst, C. Penley, Hanfei Lu, Sergei Drizlikh

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Abstract

By using fluorocarbon gases for aluminum (Al) pad open plasma etch, the pad inevitably has a thin surface remnant layer of Al-oxyfluoride (AlOF) by-product. This layer is chemically stable and does not directly cause issues in chip testing or wire bonding. This is true until open Al pads were exposed to a humid environment causing pad corrosion over time. The F-assisted corrosion created so-called black mushroom (BM) defects on the Al pads according to the defects appearance, resulting in the non-stick pads for wire bonding. Experimental tests were carried out to induce the Al pad corrosion via placing random fab-out wafers in a cassette pod hosting about 90% RH over a period up to a week. Optical imaging revealed BMs nucleated, primarily at Al grain boundaries. BMs were found all to be composed of O, F, and Al. In the cross section, BMs were shown to have separations of F-rich region next to Al and O-rich region towards the surface. In addition, BMs were composed of small crystallites and were porous. The former indicates an ionic bonding involving in O, F, and Al. The latter indicates the corrosion generated gaseous byproduct. A moisture (H2O) involved cyclic chemical reaction incorporating these analyses has been formulated. Factors to prevent BM formation were discussed.

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黑色蘑菇形成铝键垫

采用氟碳气体对铝(Al)焊盘进行开放式等离子蚀刻，焊盘表面不可避免地会残留一层薄薄的氧化氟化铝(AlOF)副产物。这一层是化学稳定的，不会直接导致芯片测试或电线粘合问题。这是正确的，直到开放的铝垫暴露在潮湿的环境中，随着时间的推移导致垫腐蚀。根据缺陷的外观，f辅助腐蚀在Al焊盘上产生了所谓的黑蘑菇(BM)缺陷，导致焊盘不粘焊。在长达一周的时间里，通过将随机的晶圆片放置在RH约为90%的盒式吊舱中，进行了诱导Al衬垫腐蚀的实验测试。光学成像显示bm主要在Al晶界处成核。bm均由O、F和Al组成。在横截面上，bm在靠近Al的地方有富F区和靠近表面的富O区分离。此外，BMs由小晶体组成，具有多孔性。前者表示O、F和Al中存在离子键，后者表示腐蚀产生的气态副产物。一个水分(H2O)涉及循环化学反应结合这些分析已制定。讨论了防止BM形成的因素。

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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International Symposium for Testing and Failure Analysis

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