Computational study for electronic interconnects and performance of solders and solder paste

2021 IEEE 66th Holm Conference on Electrical Contacts (HLM) Pub Date : 2021-10-24 DOI:10.1109/HLM51431.2021.9671144

Waliul Matin, M. Morrison, KhanFareed Ashraf

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引用次数: 1

Abstract

The interconnect contacts consisting of solder act as bottleneck in terms of reliability in electronic chips. Computations have been performed to investigate the efficacy of solders considering traditional ones and solder paste. The study focuses on solders and solder paste that can operate at various thermal load and material structures. In this study, Quilt Packaging, QP, Thru Silicon Via, TSV, and Flip chip structures have been utilized to find the effectiveness of the solders. The electroless solder or solder pastes are applied in narrow interconnect as done in quilt packaging, whereas other solders are used in wide connections that can carry substantial currents as observed in traditional interconnects. The chip as well as the interconnects can generate heat during operation; specifically, in hot spots, it can produce large temperature gradient resulting in increased thermal stress. The simulation demonstrates structural deformation due to dielectric or resistive heating. With the available fatigue parameters for the solders, plastic strain and failure have been computed for the structures. Finally, with the mentioned constraints, the simulation results indicate the material parameters to focus on when selecting solders.

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电子互连及焊料和锡膏性能的计算研究

由焊料组成的互连触点是电子芯片可靠性的瓶颈。计算了传统焊料和锡膏两种焊料的焊接效果。研究的重点是可以在各种热负荷和材料结构下工作的焊料和锡膏。在本研究中，利用被覆封装、QP、透硅通孔、TSV和倒装芯片结构来发现焊料的有效性。化学焊料或焊膏应用于窄互连中，如被子封装中所做的，而其他焊料用于宽连接中，如传统互连中所观察到的，可以携带大量电流。芯片以及互连在运行过程中会产生热量;具体来说，在热点处，它会产生较大的温度梯度，导致热应力增大。模拟显示了由于介电或电阻加热引起的结构变形。利用可用的焊料疲劳参数，计算了结构的塑性应变和破坏。最后，结合上述约束条件，给出了在选择焊料时应注意的材料参数。

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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2021 IEEE 66th Holm Conference on Electrical Contacts (HLM)

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