Composite Soldering Materials Based on BiSnAg for High-Temperature Stable Solder Joints

Q4 Engineering

Journal of Microelectronics and Electronic Packaging Pub Date : 2022-10-01 DOI:10.4071/001c.57716

A. Novikov, M. Nowottnick

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引用次数: 0

Abstract

The thermal load on electronic assemblies is constantly increasing. The reasons for this increase are, on the one hand, the integration of power electronic components in an ever smaller space and, thus, an increasing power density and, on the other hand, the increasingly harsh environmental conditions with high temperature load. In addition to electronic components and substrate materials, the soldered connections are also exposed to this stress and must withstand it. The thermal stability is primarily determined by the melting temperature of the solder material or by the remelting temperature of the final solder interconnection. The remelting temperature can be purposefully increased through diffusion soldering. The advantage of diffusion soldering is that the operating temperature of the final solder joint can exceed the joining process temperatures. By using the composite soldering materials and diffusion soldering process, it is possible to produce the solder interconnections that can withstand the high thermal and thermomechanical stress. In this work, the composite solder material, consisting of the base solder alloy BiSnAg in eutectic composition with a melting point of 139 degrees C and added copper particles, was examined. The added copper particles have a direct influence on the dynamics of the diffusion process. Diffusion can also be influenced by adjusting the soldering process parameters, such as maximum temperature and time above liquidus of the base solder alloy, with the aim of achieving isothermal solidification. The solidification can take place through the parallel reactions: the reaction between tin and copper with the formation of high-melting intermetallic phases Cu3Sn and Cu6Sn5 and the growth of bismuth (Bi) crystals through coarsening of the structure and tin depletion in the original eutectic solder alloy.

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基于BiSnAg的高温稳定焊点复合钎焊材料

电子组件上的热负荷不断增加。这种增加的原因一方面是功率电子部件集成在越来越小的空间中，因此功率密度增加，另一方面是高温负载的环境条件越来越恶劣。除了电子元件和基板材料外，焊接连接也暴露在这种应力下，并且必须承受这种应力。热稳定性主要由焊接材料的熔化温度或最终焊接互连的重熔温度决定。通过扩散焊接可以有目的地提高重熔温度。扩散焊接的优点是最终焊点的操作温度可以超过接合工艺温度。通过使用复合焊接材料和扩散焊接工艺，可以产生能够承受高热和热机械应力的焊料互连。在这项工作中，研究了由熔点为139摄氏度的共晶成分的基底焊料合金BiSnAg和添加的铜颗粒组成的复合焊料材料。添加的铜颗粒对扩散过程的动力学有直接影响。扩散也可以通过调整焊接工艺参数来影响，例如基底焊料合金的液相线以上的最高温度和时间，目的是实现等温固化。凝固可以通过平行反应进行：锡和铜之间的反应，形成高熔点的金属间相Cu3Sn和Cu6Sn5，以及铋（Bi）晶体的生长，通过原始共晶焊料合金中结构的粗化和锡的耗尽。

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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来源期刊

Journal of Microelectronics and Electronic Packaging Engineering-Electrical and Electronic Engineering

CiteScore

1.30

自引率

0.00%

发文量

期刊介绍： The International Microelectronics And Packaging Society (IMAPS) is the largest society dedicated to the advancement and growth of microelectronics and electronics packaging technologies through professional education. The Society’s portfolio of technologies is disseminated through symposia, conferences, workshops, professional development courses and other efforts. IMAPS currently has more than 4,000 members in the United States and more than 4,000 international members around the world.