Solder Paste Additives for Thermal Expansion Control

Volume 3: Advanced Materials: Design, Processing, Characterization, and Applications Pub Date : 2021-11-01 DOI:10.1115/imece2021-72478

P. Capela, M. S. Souza, S. Costa, M. Fernandes, H. Figueiredo, R. Alves, I. Delgado, J. Teixeira, D. Soares

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Abstract

Most electronic failures that occur in equipment are due to stresses induced by differences in the Coefficient of Thermal Expansion (CTE) of the different materials in a Printed Circuit Board Assemblies (PCBA). During a thermal cycle, the incompatibility of CTE between the PCB and the components induces shear fatigue that may affect the reliability of the solder interconnections on the PCB, which can eventually lead to fracture and failure of the joints and the PCB. Due to the advancement in the electronic components industry, interest from the researcher’s point of view has grown in studying the influence of additives in the solder alloys, in relation to microstructure, physical and mechanical properties and, mainly in the CTE. In this work two types of additives (Bi and graphite powder) were tested in order to reduce the CTE of a lead-free solder (SAC305) solder paste for reflow soldering. Because the selected additives have different characteristics, namely different densities, a different method of SAC305 solder additivation was tested for each type of additive. For Bi addition in SAC305 alloy (up to 6.5 wt.%), after a mechanical mixing of it, with the solder paste, a fusion technique (with a thermal cycle similar to the used on the reflow soldering) was used. For composites with graphite (addition up to 0.1 wt.%) a double-printing method was used in order to achieve a homogeneous additive distribution, so that graphite remained in the final ingot. These additivated solder alloys were chemically analyzed and characterized for thermogravimetric properties. Samples microstructure were characterized by SEM/EDS analysis, and also they were tested for their electrical resistivity. With graphite addition there is a slight increase on the initial alloy melting temperature (∼1.5°C) and with Bi an almost linear decrease was obtained (∼16 °C for the higher tested Bi addition). Composites with bismuth have a decrease trend, with the additive increase content until close to 5%. The CTE value decreases almost linearly ((from 25 to ∼14.5 μm/(m·°C); R2 = 0.9905). However, the sample of SAC305 + 6.5% Bi does not follow this trend, which may indicate that for these and higher amounts of bismuth, the composite CTE stabilizes. For composites with graphite there is a reduction of CTE (from 25 to ∼17 μm/(m·°C) for 0.04 wt. % graphite addition). For higher graphite additions the CTE seems to increase. The obtained results show that both additives can be used in order to achieve a CTE target value close to the PCB copper PAD (17 μm/(m·°C). However, the mixing method used for graphite mixing on solder paste cannot be directly transposed to the reflow soldering technique.

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用于热膨胀控制的锡膏添加剂

设备中发生的大多数电子故障是由于印刷电路板组件(PCBA)中不同材料的热膨胀系数(CTE)差异引起的应力引起的。在热循环过程中，PCB与组件之间的CTE不兼容会产生剪切疲劳，从而影响PCB上焊料互连的可靠性，最终导致接头和PCB的断裂和失效。由于电子元件工业的进步，从研究人员的角度来看，研究焊料合金中添加剂对微观结构、物理和机械性能的影响，主要是在CTE方面的影响越来越大。为了降低一种用于回流焊的无铅焊料(SAC305)锡膏的CTE，本文对两种添加剂(铋和石墨粉)进行了测试。由于所选择的添加剂具有不同的特性，即不同的密度，因此对每种类型的添加剂进行了不同的SAC305焊料添加方法测试。对于在SAC305合金中添加Bi(高达6.5% wt.%)，在将其与锡膏进行机械混合后，使用熔化技术(与回流焊接中使用的热循环相似)。对于含有石墨的复合材料(添加量高达0.1 wt.%)，采用双重印刷方法，以实现均匀的添加剂分布，使石墨留在最终铸锭中。对这些钎料合金进行了化学分析和热重表征。采用SEM/EDS对样品的微观结构进行了表征，并进行了电阻率测试。随着石墨的加入，合金的初始熔化温度略有升高(~ 1.5°C)，而随着Bi的加入，合金的熔化温度几乎呈线性下降(对于较高的Bi添加量，合金的熔化温度为~ 16°C)。添加铋的复合材料随添加剂含量的增加有降低的趋势，直到接近5%。CTE值几乎呈线性下降(从25 ~ ~ 14.5 μm/(m·°C);R2 = 0.9905)。然而，SAC305 + 6.5% Bi的样品没有遵循这一趋势，这可能表明对于这些和更高量的铋，复合CTE稳定。对于石墨复合材料，CTE降低(0.04 wt. %的石墨添加量从25 μm/(m·°C)降至~ 17 μm/(m·°C))。对于较高的石墨添加量，CTE似乎有所增加。结果表明，两种添加剂均可使CTE的目标值接近PCB铜PAD (17 μm/(m·°C))。然而，在锡膏上混合石墨的混合方法不能直接转置到回流焊接技术中。

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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Volume 3: Advanced Materials: Design, Processing, Characterization, and Applications

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