Study and Application of Nano Copper Sintering Technology in Power Electronics Packaging

Xu Liu, Quan Zhou, Xu Zhao, S. Koh, H. Ye, Guoqi Zhang
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Abstract

Nano-metal sintering has been proven to be a promising die attachment technology for power electronics packaging in the high-end application. Compared with nano silver technology, it is believed that copper-based sintering technology has better cost and performance superiority, and thus has more potential to be utilized in the industry in the future. However, most of the current developed nano copper sintering material and technology shows bad performance with high sintering energy input. In this study, a novel nano-copper based paste has been developed with excellent process ability (sinterable below 280°C for 10 min with low pressure assisted) and good material property (over 40 MPa shear strength), which turns out to be suitable for the state-of-the-art packaging process. Then the material was applied into a SiC power module packaging scenario which shows comparable performance as silver sintering. The whole process only consumed less than 0.5h for each batch, which indicates that the copper sintering technology has great potential for the packaging application in high power situation.
纳米铜烧结技术在电力电子封装中的研究与应用
纳米金属烧结技术在电力电子封装的高端应用中已被证明是一种很有前途的贴装技术。与纳米银技术相比,铜基烧结技术具有更好的成本和性能优势,未来具有更大的工业应用潜力。然而,目前开发的纳米铜烧结材料和工艺大多存在烧结能量大、烧结性能差的问题。在本研究中,开发了一种新型纳米铜基浆料,具有优异的工艺性能(可在280℃以下低压辅助下烧结10 min)和良好的材料性能(抗剪强度超过40 MPa),适用于最先进的包装工艺。然后将该材料应用于SiC功率模块封装场景,显示出与银烧结相当的性能。整个过程每批仅消耗不到0.5h,表明铜烧结技术在大功率场合的封装应用具有很大的潜力。
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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