In this paper a three-dimensional (3D) chip stacking technology using fine-pitched interconnects with lead-free solder is described. Different interconnect metallurgies such as Cu/Ni/In, Cu/In and Cu/Sn were considered and the bonding conditions to optimize the bonding parameters were determined. The effect of intermetallic compound (IMC) formation on the mechanical properties of the joins is discussed. Unlike standard 100-micron C4 solder balls, very small solder volumes (< 6 microns high) were investigated. The mechanical properties were evaluated by shear and impact shock testing, while scanning electron microscopy (SEM) and optical microscopy were used to study the morphology of the IMC layers in solder joins before and after annealing. It was found that Cu/Ni/In and Cu/In interconnections have slightly lower shear strength per bump. While these values were lower than the Cu/Sn joins, the Cu/Ni/In chips passed the impact shock test for a simulated heat sink mass of 27g/cm2. The reasons for the differences in reliability of these metallurgies are discussed. 3D chip stacking using two-layers of chips with fine-pitch lead-free interconnects was demonstrated. The resistance of link chains comprising through-vias, lead-free interconnects and Cu links were measured using a 4-point probing method. The average resistance of the through-via including the lead-free interconnect was 21 m驴.
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机译:本文描述了一种使用精细间距互连与无铅焊料的三维(3D)芯片堆叠技术。考虑了不同的互连冶金,例如Cu / Ni / In,Cu / In和Cu / Sn,并确定了优化键合参数的键合条件。讨论了金属间化合物(IMC)的形成对接头机械性能的影响。与标准的100微米C4焊球不同,我们研究了非常小的焊锡量(<6微米高)。力学性能通过剪切和冲击冲击测试进行评估,而扫描电子显微镜(SEM)和光学显微镜则用于研究退火前后焊缝中IMC层的形貌。发现Cu / Ni / In和Cu / In互连具有每个凸点的较低的剪切强度。尽管这些值低于Cu / Sn连接量,但Cu / Ni / In芯片通过了冲击冲击试验,模拟的散热片质量为27g / cm2。讨论了这些冶金学可靠性差异的原因。演示了使用两层带有细间距无铅互连的芯片的3D芯片堆叠。使用四点探测方法测量包括通孔,无铅互连和Cu链接的链接链的电阻。包括无铅互连的通孔的平均电阻为21 m驴。
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