Nanomechanical characterization of IMCs formed in SAC solder joints subjected to isothermal aging

2017 16th IEEE Intersociety Conference on Thermal and Thermomechanical Phenomena in Electronic Systems (ITherm) Pub Date : 2017-05-01 DOI:10.1109/ITHERM.2017.7992645

Abdullah Fahim, Sudan Ahmed, J. Suhling, P. Lall

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引用次数: 5

Abstract

Isothermal aging of lead-free Sn-Ag-Cu (SAC) solder joints leads to growth of intermetallic (IMC) particles in the solder bulk as well as growth of intermetallic layers at the joint interfaces with copper bond pads. Fracturing near the interfacial IMC layers is often found to be the primary reason for failures caused by drop impacts. The IMCs in SAC joints are primarily AgsSn and Cu6Sn5 binary compounds. Cu-Ni-Sn based ternary IMCs can also form at the interface of Ni containing surface finish (i.e. ENIG) and SAC solder. The mechanical properties of these IMCs are very different than those of the Sn rich dendrites and Cu pads. Nanoindentation (NI) techniques are powerful tools to characterize mechanical properties of small particles and thin layers. In this study, the mechanical behaviors of IMC particles and layers in SAC solder joints have been characterized using nanoindentation. SAC bga solder joints were first aged for 6 months at T = 125 °C. Test samples were subsequently prepared by cross-sectioning the aged solder joints, and then molding them in epoxy and polishing them to prepare the joint surfaces for microscopy and nanoindentation. Intermetallics formed in the bulk solder region, copper pad and SAC solder interface, and ENIG plating finish and SAC solder interface were observed and detected using SEM and the energy-dispersive x-ray spectroscopy (EDX) technique. The same intermetallics were then indented to measure their room temperature mechanical properties including the elastic modulus, hardness, and creep strain rate. To ensure the indentation occurred at the desired phase, SPM imaging was done prior and after the indentations. As expected, the measured properties of the IMCs were significantly higher than the Sn-matrix forming the solder joints. The measured elastic modulus and hardness values were 98.1 ± 6.3 and 5.80 ± 0.70 GPa for the Cu6Sn5 layers at the joint and copper bond pad interfaces, 132.5 ± 4.5 and 8.58 ± 1.13 GPa for the Cu1-x Nix)6Sn5 layers at the joint and ENIG plating finish interfaces, and 75.2 ± 4.0 and 3.085 ± 0.50 GPa for the AgsSn IMC particles in the solder joint bulk. These are all much higher than the values of 42.7 ± 2.3 and 0.21 ± 0.12 GPa measured for the β-Sn phase in the solder joint bulk. Creep testing performed at 25 °C revealed that the (Cu1−xNix)6Sn5 IMC layers had the lowest steady state secondary creep rate of 1.088 × 10⁻³ sec⁻¹, whereas the Cu6Sn5 layers had a creep rate of 1.66 × 10⁻³ sec⁻¹, and the AgsSn IMC particles had a creep rate of 2.34 ×10⁻³ s⁻¹. The creep stress exponents were evaluated from log-log plots of the strain rate vs. applied stress data.

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等温时效下SAC焊点形成IMCs的纳米力学表征

无铅Sn-Ag-Cu (SAC)焊点的等温时效导致钎料体中金属间颗粒(IMC)的生长，以及铜焊盘连接界面处金属间层的生长。界面内压层附近的压裂通常被认为是由液滴冲击引起的破坏的主要原因。SAC接头中的IMCs主要为AgsSn和Cu6Sn5二元化合物。Cu-Ni-Sn基三元IMCs也可以在含Ni表面光面(即ENIG)和SAC焊料的界面上形成。这些IMCs的力学性能与富锡枝晶和Cu衬垫的力学性能有很大的不同。纳米压痕(NI)技术是表征小颗粒和薄层机械性能的有力工具。本研究利用纳米压痕技术对SAC焊点中IMC颗粒和层的力学行为进行了表征。SAC bga焊点在T = 125℃下首次时效6个月。随后，通过对老化焊点进行横切，然后在环氧树脂中成型并抛光来制备测试样品，以制备用于显微镜和纳米压痕的连接表面。利用扫描电镜(SEM)和能量色散x射线能谱(EDX)技术观察和检测了在大块焊点区、铜垫和SAC焊点界面、ENIG镀面和SAC焊点界面形成的金属间化合物。然后将相同的金属间化合物压痕以测量其室温力学性能，包括弹性模量，硬度和蠕变应变率。为了确保压痕发生在所需的阶段，在压痕之前和之后都进行了SPM成像。正如预期的那样，IMCs的测量性能明显高于形成焊点的sn基体。结果表明:cu -x - Nix - 6Sn5层的弹性模量和硬度分别为98.1±6.3和5.80±0.70 GPa, cu -x - Nix - 6Sn5层的弹性模量和硬度分别为132.5±4.5和8.58±1.13 GPa，钎料体中AgsSn - IMC颗粒的弹性模量和硬度分别为75.2±4.0和3.085±0.50 GPa。这些都远高于焊点体中β-Sn相的42.7±2.3和0.21±0.12 GPa。在25℃下进行的蠕变试验表明，(Cu1−xNix)6Sn5 IMC颗粒的稳态二次蠕变速率最低，为1.088 ×10−3 sec−1，而Cu6Sn5 IMC颗粒的蠕变速率为1.66 ×10−3 sec−1,AgsSn IMC颗粒的蠕变速率为2.34 ×10−3 s−1。蠕变应力指数由应变速率与施加应力数据的对数图来评估。

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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2017 16th IEEE Intersociety Conference on Thermal and Thermomechanical Phenomena in Electronic Systems (ITherm)

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