Process-Reliability Relationships of SnBiAg and SnIn Solders for Component Attachment on Flexible Direct-Write Additive Circuits in Wearable Applications

2022 IEEE 72nd Electronic Components and Technology Conference (ECTC) Pub Date : 2022-05-01 DOI:10.1109/ectc51906.2022.00189

P. Lall, Jinesh Narangaparambil, Scott Miller

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引用次数: 2

Abstract

Realization of flexible hybrid electronics using additively printed circuits requires the development of component attachment methods with low-temperature processing. Additive electronics may be fabricated on a variety of substrates including Polyimide, PET, PEN. While polyimide may be processed at normal reflow temperatures, thermally stabilized PET and PEN require a peak processing temperature less than 150 °C. A number of new solder materials have emerged capable of being processed at temperatures in the range of 130-150 °C. Low-temperature processing has additional benefits of lower warpage, lower energy consumption and lower carbon footprint. In this paper, the process-performance-reliability relationships have been studied for Sn-Bi-Ag and Sn-In solders on additively printed copper metallization. Process-recipes have been developed for direct write additive printer for fabrication of single layer and multilayer flexible circuits. Copper ink is a good and cost-effective alternative to silver ink, but its use has lagged owing to an increased propensity for oxidation. In this paper, photonic curing has been used to sinter copper ink to make the traces conductive. The method flashes high energy light that sinter metal particles instantaneously and the temperature of the substrate remains low. The effect of the different photonic sintering profiles on the mechanical and electrical properties of the printed traces has been studied. Electrical and mechanical performance has been studied through characterization of the frequency-performance of low-pass filters, high-pass filters and amplifiers fabricated using surface mount components on additively printed metallization. Reliability and the performance degradation of the additively printed circuits has been quantified in flex-to-install applications. In addition, SEM/EDAX has been used to study the intermetallics at the interface of LTS and additively printed circuits.

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可穿戴柔性直写电路中元件连接SnBiAg和SnIn焊料的工艺可靠性关系

利用增材印刷电路实现柔性混合电子需要开发具有低温加工的元件附着方法。增材电子元件可以在各种衬底上制造，包括聚酰亚胺，PET, PEN。虽然聚酰亚胺可以在正常回流温度下加工，但热稳定PET和PEN需要的峰值加工温度低于150°C。许多新的焊料材料已经出现，能够在130-150°C的温度范围内进行加工。低温加工具有低翘曲，低能耗和低碳足迹的额外好处。本文研究了增材印刷铜金属化过程中Sn-Bi-Ag和Sn-In焊料的工艺-性能-可靠性关系。开发了用于制造单层和多层柔性电路的直写式增材打印机的工艺配方。铜油墨是银油墨的一种很好的和具有成本效益的替代品，但由于氧化倾向增加，其使用滞后。本文采用光子固化的方法烧结铜油墨，使其导电。该方法发出高能量光，使金属颗粒瞬间烧结，衬底温度保持较低。研究了不同的光子烧结方式对印制线力学性能和电学性能的影响。通过表征使用增材印刷金属化表面贴装元件制造的低通滤波器、高通滤波器和放大器的频率性能，研究了电气和机械性能。在柔性安装应用中，增材印刷电路的可靠性和性能退化已经被量化。此外，利用SEM/EDAX研究了LTS和增材印刷电路界面上的金属间化合物。

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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2022 IEEE 72nd Electronic Components and Technology Conference (ECTC)

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