Thermal Cycling and Fatigue Life Analysis of a Laterally Conducting GaN-based Power Package

2023 IEEE International 3D Systems Integration Conference (3DIC) Pub Date : 2023-05-10 DOI:10.1109/3DIC57175.2023.10154901

Pouria Zaghari, Sourish S. Sinha, J. Ryu, P. Franzon, D. Hopkins

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Abstract

Thermal reliability is a critical factor in ensuring the performance and efficiency of GaN-based electronic devices. In this paper, the fatigue life assessment of a laterally conducting GaN power package that uses a two-solder hierarchy of SAC305 and Sn63/Pb37 on a 120μm thick dielectric for device attach was conducted using an FEA. The double-sided package structure also introduced thick Cu as integrated baseplate layers for mechanical mounting into higher packaging levels while providing surfaces for double-sided cooling. The internal structure varied spacer thicknesses for planarization and inclusion of package-integrated decoupling capacitors. The solder materials were simulated by using the Anand viscoplastic constitutive model. Coffin-Manson, Engelmaier, and Solomon empirical strain-based models were utilized to predict the cyclic life of the package. Based on the results, the critical solder joint location was predicted in the Sn63/Pb37 solder layer between the GaN and Cu spacer, with a strain range of 0.02797. The worst-case life prediction for the module was 150 cycles using the Coffin-Manson model.

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横向导电氮化镓基电源封装的热循环和疲劳寿命分析

热可靠性是保证氮化镓电子器件性能和效率的关键因素。本文采用有限元分析方法，对采用SAC305和Sn63/Pb37两种焊料结构的横向导电GaN电源封装进行了疲劳寿命评估。双面封装结构还引入了厚铜作为集成基板层，用于机械安装到更高的封装层，同时为双面冷却提供表面。内部结构改变了间隔层厚度，以实现封装集成去耦电容器的平面化和包涵。采用Anand粘塑性本构模型对钎料进行了数值模拟。使用Coffin-Manson, Engelmaier和Solomon经验应变模型来预测包装的循环寿命。在此基础上，预测了氮化镓与铜间隔片之间Sn63/Pb37焊点层的临界焊点位置，其应变范围为0.02797。使用Coffin-Manson模型，该模块的最坏情况寿命预测为150次循环。

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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2023 IEEE International 3D Systems Integration Conference (3DIC)

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