One of the key advantages to replace bare Cu wire with Pd Cu wire in semiconductor packages is to reduce corrosion risk against halogen from mold compound or substrate soldermask outgasing. However, existing wire bond recipe development methodology adopted from bare Cu wire was less effective for Pd Cu due to harder Free Air Ball (FAB) with Pd Cu wire, causing Pd Cu bond failure after biasing reliability stress such as HAST. This study is aimed to obtain a proper methodology in developing a reliable Pd Cu wire bond recipe. In this study,Step # 1 was to determine the best method to study Pd distribution in FAB and bonded ball surface. For Pd distribution on FAB surface, 2 methods were studied: 1. inspection under high power optical scope; 2. soaking into Nitric Acid and Ferric Chloride. For Pd distribution on bonded ball surface, the 2 methods explored were SEM vs EPMA after cross-sectioning of the bonded ball.Step # 2 was to conduct a DOE with different EFO current and time to obtain optimum Pd distribution surrounding the bonded ball.Step # 3 was to down select EFO current and time that provided optimum Pd distribution and bondability.Step # 4 was to proceed with wire bond parameters derivation through comprehensive design of experiments (DOE) and response surface methodology (RSM) to establish the bonding parameter window.Step # 5 was to subject the bonded and molded units for reliability stressing which has biasing stress, such as HAST or THB. Upon completion of the study, a systematic flow was established and applied to a test vehicle of C90 wafer technology in a thermally enhanced 31x31mm 689TePBGA-II. The result showed that the established flow was effective to prevent any failure in biasing stress, where 3 lots x 80 units had passed 1008hrs THB and 3 lots x 25 units has passed 2016hrs THB.
As gold price continues to move in an overall rising trend, conversion to Cu wire has been given great focus as the main effort for cost reduction. Cu is a good alternative due to 26% lower electrical resistivity than Au, hence much higher electrical conductivity. However, Cu free-air-ball and bonded ball hardness are 34% and 60% higher than that of Au, hence increases the stress on bond pad and chip. Although Cu wire price is generally only 5 to 10% of Au wire cost depending on wire diameter, but bonding with a much harder material like Cu requires great characterization effort due to the a much higher level of unknowns and complexities, especially when dealing with ultra fine pitch and ultra low k wafer technology.This study is aimed to share the success story of Cu wire bond process characterization for C45 ultra low k wafer technology with bond-over-active bond pads, on a thermally enhanced BGA package with 31x31mm large body size. With Al bond pad thickness at 2.1um, the combination in this study represents the highest difficulty level in Cu wire bonding due to potentially high pad damage and Al splash, and possibly higher bond failure due to BGA substrate outgasing.Along with the challenging wafer technology comes the small bond pad opening at 40um. In view of such small bond pad opening, and a typically higher Al splash with Cu wire, hence the maximum ball size was targeted at 30um. Wire diameter was fixed at 18um to ensure good wire-to-bonded ball ratio, as well as to allow a good capillary design. The latest generation wire bonder was used to ensure the best bond placement accuracy at +/-2um, as well as to minimize bond pad damage through higher bond force resolution.The characterization process started with selection of capillary, followed by selection of Cu wire, both with certain level of bonding parameters optimization.For capillary selection, the best 3 capillaries with high success rate in the semiconductor industry for Cu wire bonding were selected. Each of the capillary had different features as a technology edge from the different suppliers.The key responses were 2 nd bond peel strength and 1 st bond Al remnant. Out of the 3 capillaries, the best was selected based on highest 2 nd bond peel and Al remnant through a thorough DOE process. During this stage, it was also found that Cu Kit with an extended coverage at bonding zone was an important
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