A Drop-In High-Temperature Pb-Free Solder Paste That Outperforms High-Pb Pastes in Power Discrete Applications

Q4 Engineering

Journal of Microelectronics and Electronic Packaging Pub Date : 2023-04-01 DOI:10.4071/001c.81981

Hongwen Zhang, Tyler Richmond, Kyle Aserian, Samuel Lytwynec, Tybarius Harter, Diego Prado

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引用次数: 0

Abstract

Sn-based high-temperature Pb-free (HTLF) solder pastes have been developed as a drop-in solution to replace high- Pb solder pastes in power discrete applications. The pastes were designed with Indium Corporation’s DurafuseVR technology, to combine the merits of two constituent powders. A SnSb-based Ag/ Cu-containing high-temperature powder, with a melting temperature above 320 degrees C, was designed to maintain high-temperature performance. A Sn-rich SnAgCu-Sb powder, with a melting temperature around 228 degrees C, was added to the paste to enhance wetting and improve joint ductility. In the design, the final joint will have the low-melting phase (the melting temperature >228 degrees C) in a controllable quantity embedded into the high-melting SnSb matrix. HTLF-1, one of the designs, maintained the bond shear strength up to 15 MPa, even around 290 degrees C. Another design, HTLF-2, has a similar bond shear strength as Pb92.5/Sn5/Ag2.5 around 290 degrees C, but exceeds substantially below 250 degrees C. The power discrete components had been built with both HTLF solder pastes for both die-attach and clip-bond through the traditional high-Pb process, which demonstrated the drop-in processing compatibility. The components survived three additional surface mounting (SMT) reflows (peak temperature upto 260 degrees C) and passed moisture sensitivity level 1 (MSL1). This confirmed that the maintained joint strength (comparable to or stronger than high-Pb), helped to keep the joint integrity within the encapsulated components in the following SMT process, even with the controlled quantity of the melting phases above 228 degrees C. Both HTLF solder pastes outperformed Pb92.5/Sn5/Ag2.5 in the resistance from drain to source when power is on (RDS(on)), even after 1,000 cycles of temperature cycling test (TCT) under 255/175 degrees C, which is attributed to the intrinsic lower electrical resistivity of Sn in both HTLF pastes. Microstructural observation had shown no corner cracks for both die-attach and clip-bond joints after TCT.

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一种插入式高温无铅焊膏，在电源分立应用中优于高铅焊膏

锡基高温无铅(HTLF)焊锡膏已经发展成为一种替代高铅焊锡膏在电源分立应用中的替代方案。这些浆料是用铟公司的DurafuseVR技术设计的，结合了两种成分粉末的优点。为了保持高温性能，设计了一种熔点在320℃以上的snsb基含Ag/ cu高温粉末。在膏体中加入一种富含sn的SnAgCu-Sb粉末，其熔化温度约为228℃，以增强润湿性并提高接头的延展性。在设计中，最终接头将可控数量的低熔点(熔点温度>228℃)嵌入高熔点SnSb基体中。其中一种设计HTLF-1，即使在290℃左右，也能保持高达15 MPa的键合剪切强度。另一种设计HTLF-2，在290℃左右的键合剪切强度与Pb92.5/Sn5/Ag2.5相似，但在250℃以下的键合剪切强度大大超过了Pb92.5/Sn5/Ag2.5。通过传统的高铅工艺，HTLF焊膏可用于模贴和夹贴，这表明了其加工相容性。这些组件经受住了三次额外的表面安装(SMT)回流(峰值温度高达260摄氏度)，并通过了水分敏感等级1 (MSL1)。这证实，在接下来的SMT工艺中，即使在228℃以上的熔化相数量受控的情况下，保持接头强度(与高铅相当或更强)有助于保持封装组件内的接头完整性。HTLF焊膏在通电时(RDS(on))从漏极到源极的电阻优于Pb92.5/Sn5/Ag2.5，即使在255/175℃下进行1000次温度循环测试(TCT)后也是如此。这是由于两种HTLF膏体中Sn的固有电阻率较低。显微组织观察显示，TCT后模接和夹接接头均无拐角裂纹。

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

Journal of Microelectronics and Electronic Packaging Engineering-Electrical and Electronic Engineering

CiteScore

1.30

自引率

0.00%

发文量

期刊介绍： The International Microelectronics And Packaging Society (IMAPS) is the largest society dedicated to the advancement and growth of microelectronics and electronics packaging technologies through professional education. The Society’s portfolio of technologies is disseminated through symposia, conferences, workshops, professional development courses and other efforts. IMAPS currently has more than 4,000 members in the United States and more than 4,000 international members around the world.