基于低温In/ Au IMC键合方法的薄模堆积

2009 11th Electronics Packaging Technology Conference Pub Date : 2009-12-01 DOI:10.1109/EPTC.2009.5416503

Siong Chiew Ong, W. Choi, C. Premachandran, E. Liao, Ling Xie

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引用次数: 3

摘要

在200℃以下的低温条件下，采用In-alloy在Au上进行低温焊接，形成高重熔温度(约300℃)的坚固的金属间化合物(IMC)接头，使IMC接头在焊接后能够承受后续工艺而不发生劣化。采用类似的焊料系统和方法，开发了芯片到晶圆(C2W)键合方法，因为这种芯片在最终键合之前暂时键合到晶圆上。通过两个顺序键合条件将芯片键合到晶圆上;在200/90˚C(芯片/晶圆)和180/180˚C下进行20秒和5分钟的最终粘合。采用扫描电镜(SEM)和透射电镜(TEM)对IMC接头的显微组织和成分进行了评价。结果表明，该接头完全被Au-In基IMC相占据。IMC接头抗拉强度为120~330N (23.5~38.8MPa)。在此基础上，采用芯片-晶圆叠加的方法，制备了3个具有8×8 mm2晶片、~1700 I/ o、80um焊点的堆叠晶片。在每一层的整个模具上显示出均匀的结合，并取得了较好的抗拉强度。并在260℃下进行3次再流试验。在回流试验后对IMC接头进行了检查，结合后的样品既没有出现脱层现象，也没有出现组织变化。

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Thin die stacking by low temperature In/ Au IMC based bonding method

Low temperature bonding technology is developed using In-alloy on Au at a low temperature below 200˚C forming robust intermetallics (IMC) joints with high re-melting temperature (>300˚C), so that after bonding the IMC joints can withstand the subsequent processes without any degradation. Using similarly solder system and methodology, chips to wafer (C2W) bonding method has been developed, as such chips are temporary bonded onto wafer before the final bonding. The chips are bonded onto the wafer by two sequential bonding condition; temporary followed by a final bonding, which is 200/90˚C (chip/wafer) for 20sec and 180/180˚C for 5mins. The IMC joints are evaluated in terms of microstructure and compositional observations by means of scanning electron microscope (SEM) and transmittance electron microscope (TEM). As a result, it was confirmed that the joint was completely occupied with the Au-In based IMC phases. These IMC joint showed a tensile strength of 120~330N (23.5~38.8MPa). Based on this study, the 3 stacked dice with 8×8 mm2 dies with ~1700 I/Os of 80um solder bumps were fabricated in a chip to wafer stacking method. It showed uniform bonding all over the die in each layer with relatively good tensile strength achieved. Furthermore, it also underwent 3 times reflow test at 260˚C. The IMC joint was examined after going through the reflows test and the bonded samples exhibited neither de-lamination nor any changes in the microstructure.

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来源期刊

2009 11th Electronics Packaging Technology Conference

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