高温跌落冲击测试分析:评估 BGA 组件中 SAC305 焊接合金的可靠性

IF 2.3 3区 工程技术 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC
Palash Pranav Vyas;Ali Alahmer;Sergio Bolanos;Seyed Soroosh Alavi;Sa’d Hamasha
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引用次数: 0

摘要

由于铅基合金对环境的影响,电子行业越来越重视锡银铜(SAC)合金的可靠性。考虑到便携式电子设备在通常使用过程中会频繁发生跌落,因此保证稳健的板级跌落冲击可靠性对于确保其最佳性能和使用寿命至关重要。传统的跌落冲击测试主要是在室温下进行的,无法完全模拟电子电路在正常工作时受到操作或环境热应变的实际条件。针对这一知识空白,本研究旨在进行高温下的跌落冲击测试,以确保焊点在实际应用中的可靠性。在这项研究中,含有 SAC305 焊接合金的球栅阵列 (BGA) 组件在不同温度下进行了测试。跌落冲击实验按照电子器件工程联合委员会(JEDEC)跌落测试标准 JESD22- B111A 进行,峰值加速度为 1500 G,脉冲持续时间为 0.5 ms。随后,使用 Weibull 分析法评估了每种测试条件下焊点的跌落冲击可靠性。此外,还应用 Arrhenius 模型建立了跌落寿命预测模型。此外,还进行了全面的显微镜分析,以确定失效模式和随温度升高而变化的趋势。结果表明,SAC305 在室温(25 ° C)下表现出最佳性能。然而,随着温度的升高,其跌落冲击寿命明显缩短,在 50 ° C、75 ° C 和 100 ° C 时分别缩短了 64%、76% 和 78%。此外,随着温度的升高,还观察到了失效模式的转变。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Drop Shock Testing Analysis at Elevated Temperature: Assessing SAC305 Solder Alloy Reliability in BGA Assemblies
The electronics industry is increasingly prioritizing the reliability of SnAgCu (SAC)-based alloys due to environmental concerns related to lead-based alloys. Considering the frequent occurrence of drops during the typical use of portable electronic devices, guaranteeing robust board-level drop shock reliability becomes vital for ensuring their optimal performance and longevity. Traditionally, drop shock tests have predominantly been conducted at room temperature, which does not fully simulate real-world conditions where electronic circuits are subjected to operational or environmental thermal strains during the normal operation. To address this knowledge gap, this study aims to conduct drop shock tests at elevated temperatures, ensuring the reliability of solder joints in practical applications. In this study, ball grid array (BGA) assemblies containing SAC305 solder alloy were tested at various temperatures. The drop shock experiments were performed according to the Joint Electron Device Engineering Council (JEDEC) drop test standard JESD22- B111A, with a peak acceleration of 1500 G and a pulse duration of 0.5 ms. Subsequently, the drop shock reliability of the solder joints under each test condition was assessed using the Weibull analysis. In addition, the Arrhenius model was applied to develop a drop life prediction model. Furthermore, comprehensive microscopy analysis was performed to identify the failure modes and trends with increasing temperature. The results indicated that SAC305 exhibits best performance at room temperature (25 ° C). However, its drop shock lifespan significantly decreases as the temperature rises, with reductions of 64%, 76%, and 78% at 50 ° C, 75 ° C, and 100 ° C, respectively. Moreover, a failure mode transition was observed with an increase in temperature.
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来源期刊
IEEE Transactions on Components, Packaging and Manufacturing Technology
IEEE Transactions on Components, Packaging and Manufacturing Technology ENGINEERING, MANUFACTURING-ENGINEERING, ELECTRICAL & ELECTRONIC
CiteScore
4.70
自引率
13.60%
发文量
203
审稿时长
3 months
期刊介绍: IEEE Transactions on Components, Packaging, and Manufacturing Technology publishes research and application articles on modeling, design, building blocks, technical infrastructure, and analysis underpinning electronic, photonic and MEMS packaging, in addition to new developments in passive components, electrical contacts and connectors, thermal management, and device reliability; as well as the manufacture of electronics parts and assemblies, with broad coverage of design, factory modeling, assembly methods, quality, product robustness, and design-for-environment.
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