Novel Ga Assisted Low-temperature Bonding Technology for Fine-pitch Interconnects

Shan-Bo Wang, An-Hsuan Hsu, C. Kao, D. Tarng, Chien-Lung Liang, Kwang-Lung Lin
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引用次数: 1

Abstract

Thermal compression bonding (TCB) of Cu pillars at high temperature often induces undesirable warpage occurrence due to the mismatch in coefficient of thermal expansion (CTE) among heterogeneous components. Reducing the bonding temperature to avoid warpage is desirable for the development of Cu-to-Cu bonding in three-dimensional integrated circuit (3D IC) packaging.One of the approaches for lowering bonding temperature is to implement low melting temperature materials between Cu pillars. We presented in this article a novel low-temperature bonding technology for fine-pitch, less than 20 μm, Cu-to-Cu interconnects with Cu substrates. The TCB was conducted at 150°C. The low-temperature bonding was assisted by an electroplated intermediate Ga/X-alloy bilayer. The surface of the Ga layer was pre-treated with dilute sulfuric acid for better wetting behavior. The intermediate Ga layer melted and gave rise to liquid/solid interdiffusion with the X-alloy layer during the bonding according to the binary Ga-X-alloy phase diagram. The Ga component further diffused through the X-alloy layer and preferentially reacted with the Cu substrate to form thermodynamically stable CuGa2 intermetallic compound (IMC) at the Cu/X-alloy interface. The crosssectional scanning electron microscope (SEM) and focus ion beam (FIB) analyses indicated that the uniform IMC layer has around 2 μm in thickness. The energy dispersive X-ray spectroscopy (EDS) analysis showed that the electroplated Ga layer was completed consumed and mostly converted to interfacial IMC and partially dissolved in the X-alloy layer after the bonding. The microstructure characterization of the joint revealed an indistinct bonding interface with few impurities or defects, showing pronounced effect of interdiffusion during the bonding. The produced joint structure exhibited a bonding strength greater than 5 MPa as measured by a chip-scale universal testing machine. The low-temperature liquid/solid interdiffusion bonding process could be operated without the need of chemical mechanical polish (CMP). It is believed, basing on the bonding performance, that the Ga assisted low-temperature Cu-to-Cu bonding approach could be more feasible for new applications in fine-pitch 3D IC packaging.
用于细间距互连的新型镓辅助低温键合技术
高温下铜柱的热压缩键合(TCB)往往会由于非均质组分之间的热膨胀系数(CTE)不匹配而产生不良翘曲。降低键合温度以避免翘曲是三维集成电路(3D IC)封装中cu - cu键合的发展所需要的。降低键合温度的途径之一是在铜柱之间采用低熔点材料。在本文中,我们提出了一种新的低温键合技术,用于细间距(小于20 μm)的Cu-to-Cu衬底互连。TCB在150℃下进行。低温键合是通过电镀中间的Ga/ x合金双分子层来辅助的。为了获得更好的润湿性能,用稀硫酸对Ga层表面进行了预处理。根据二元Ga- x合金相图,在结合过程中,中间Ga层熔化并与x合金层发生液/固相互扩散。Ga组分进一步扩散穿过x合金层,并优先与Cu衬底反应,在Cu/ x合金界面形成热力学稳定的CuGa2金属间化合物(IMC)。扫描电镜(SEM)和聚焦离子束(FIB)分析表明,均匀的IMC层厚度约为2 μm。能谱分析(EDS)表明,电沉积的Ga层被完全消耗,大部分转化为界面IMC,并在键合后部分溶解在x合金层中。接头的微观结构表征表明,结合界面模糊,杂质和缺陷较少,在结合过程中表现出明显的相互扩散效应。通过芯片级万能试验机测试,所制备的接头结构的结合强度大于5 MPa。低温液/固互扩散粘接无需化学机械抛光(CMP)。基于键合性能,认为Ga辅助低温cu - cu键合方法在细间距3D集成电路封装中的新应用更加可行。
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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