Top side isolation investigation of PCB embedded 1.2kV dies

2021 23rd European Microelectronics and Packaging Conference & Exhibition (EMPC) Pub Date : 2021-09-13 DOI:10.23919/empc53418.2021.9584979

Luca Link, Ankit Sharma, V. Polezhaev, T. Huesgen, M. Vaas, G. Stohrer, F. Koch

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引用次数: 2

Abstract

The embedding of power electronics components into the PCB increases their thermal and electrical performance. Due to lower parasitic inductances and a lower thermal resistance, the overall power density of the system can be increased. However, there is a lack on studies about the reliability of PCB embedded power electronics, especially under humidity stress. This study uses test vehicles with functional diodes embedded into the PCB. The reliability of the test vehicles is studied under HV-H3TRB conditions. A critical leakage current is observed after 200h with a benzoxazine based prepreg and after 600h for an epoxy based prepreg. A root- cause analysis revealed lift-off of the polyimide layer and subsequent electrochemical corrosion as failure mechanism. The delamination is most likely triggered by the Au surface on the chips top metal pad. A second set of test samples was fabricated using an improved surface treatment before lamination. 75% of these samples passed the 1000h H3TRB test successfully.

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PCB内嵌1.2kV芯片的顶部隔离研究

电力电子元件嵌入到PCB中增加了它们的热和电气性能。由于较低的寄生电感和较低的热阻，系统的总功率密度可以增加。然而，对于PCB嵌入式电力电子器件的可靠性，特别是在湿度应力下的可靠性研究还比较缺乏。本研究使用功能二极管嵌入PCB的测试车辆。对试验车辆在HV-H3TRB工况下的可靠性进行了研究。用苯并恶嗪基预浸料在200h后观察到临界泄漏电流，用环氧基预浸料在600h后观察到临界泄漏电流。根本原因分析揭示了聚酰亚胺层的脱落和随后的电化学腐蚀是失效机制。剥离很可能是由薄片顶部金属衬垫上的Au表面引发的。第二组测试样品在层压前使用改进的表面处理制备。75%的样品成功通过了1000h H3TRB测试。

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

2021 23rd European Microelectronics and Packaging Conference & Exhibition (EMPC)

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