论文信息 - On the intermetallic corrosion of Cu-Al wire bonds

On the intermetallic corrosion of Cu-Al wire bonds

A detailed description of the Cu-Al wire bond interface is presented, which can possibly explain the often observed corrosion failures in humidity reliability tests. Using micro-structural analysis techniques, it is shown that the unstressed interface contains up to three intermetallic phases, where the Cu-rich phases are located at the Cu-ball interface. Upon humidity stress test only the high-Cu containing intermetallic layers close to the Cu wire ball bond undergo a corrosion process, whilst the Cu-lean layers are stable in all environment stress tests. The failing layers consist out of an amorphous Al-based oxide matrix with embedded Cu precipitates. The failure process can be explained as galvanic corrosion of the intermetallic phases. The Cu-rich phases corrode faster compared to Al-rich phases, since they have an electrochemical potential lower than the Cu cathode and form, hypothetically, a less stable self-passivation oxide. The observed time-to-failure is then determined by the composition, thickness and volume of the intermetallic layers. This was verified by reliability test results performed on open wire bonds and on plastic encapsulated products.

[1] Saraswati,et al. Characterisation of intermetallic growth in copper and gold ball bonds on aluminium metallization , 2004, Proceedings of 6th Electronics Packaging Technology Conference (EPTC 2004) (IEEE Cat. No.04EX971).

[3] Y. Zhou,et al. Growth behavior of Cu/Al intermetallic compounds and cracks in copper ball bonds during isothermal aging , 2008, Microelectron. Reliab..

[4] Ker-Chang Hsieh,et al. Bromine- and chlorine-induced degradation of gold-aluminum bonds , 2004 .

[5] R. Buchheit,et al. Investigation and Discussion of Characteristics for Intermetallic Phases Common to Aluminum Alloys as a Function of Solution pH , 2008 .

[6] C. Lee,et al. Challenges of Cu wire bonding on low-k/Cu wafers with BOA structures , 2010, 2010 Proceedings 60th Electronic Components and Technology Conference (ECTC).

[7] Katsuya Watanabe,et al. Interdiffusion in the Al–Cu System , 1971 .

[8] M. Pourbaix. Atlas of Electrochemical Equilibria in Aqueous Solutions , 1974 .

[9] John B. Shoven,et al. I , Edinburgh Medical and Surgical Journal.

[10] W. G. Proud,et al. Electrochemical studies of copper, copper-aluminium and copper-aluminium-silver alloys: Impedance results in 0.5M NaCl , 1995 .

[11] Wayne D. Kaplan,et al. Detailed investigation of ultrasonic Al–Cu wire-bonds: I. Intermetallic formation in the as-bonded state , 2008, Journal of Materials Science.