The search for an acceptable die attach solution to the European End of Life Vehicle RoHS Directive has proven problematic for the industry with several potential materials being evaluated. The mandate affects a full array of semiconductor device types from Power Modules, Smart Power ASICs to Power MOS-FETs & IGBTs in SMD and Through-Hole packages, which all contain high temperature lead containing solders until the RoHS exemption expires. Several IDMs have looked at four base material technologies: adhesives, Ag sintering, hybrid materials and solders with each one posing hurdles for mass production. The adhesives can use current equipment but are costly and have low thermal conductivity. Ag sintering has shown promising temperature cycle result but is costly and requires development of new equipment and processes. Hybrid materials can use established equipment sets but are also costly and have not been proven in high volume. There has been extensive development of solder technologies as it poses the highest likelihood of delivering a “drop in” solution to lead. Companies have spent years developing a solution that performs similarly to lead in all of the different applications. One of those solutions is Zn based alloys which have shown potential to provide a nearly drop-in solution to lead-based materials without the use of expensive precious metal or capital expenditure. Prior generations of solder development initially looked at Bismuth alloys due to the material similarities with Lead. Although Bismuth alloys are available on the market, they have two flaws that prevent them from mass adoption. The first flaw is the low thermal conductivity, achieving only 12 to 17 W/m-K. The second is the process requirement of surviving three times reflow at 260C. Since Bismuth alloys melt from 255 to 275C, they are unable to meet the reflow process constraint. This paper will focus on the development of Zn alloys for the replacement of lead in high temp- rature solders. Zinc solders overcome the two hurdles Bismuth encounters and offer a solution with thermal conductivity more than 100W/m-K and melting temperature higher than 300C. In addition, the solder material has cost benefits compared to the alternative solutions while providing improved thermal conductivity and resistivity over current lead solders. The process window of the Zn alloys are not as wide as its lead solder counterparts, requiring substantial composition and process development, and depending on device type and use, metallization requirements. Material development has lead to further understanding of intermetallic compound (IMC) formation and impacts to bond lines during reliability evaluation while using bare copper lead frames and nickel plated lead frames. Following the recommended guidelines, Zn based alloys are an acceptable alternative to lead for use within high temperature solders.
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机译:寻求对欧洲报废汽车RoHS指令可接受的管芯附着解决方案的努力已经对业界进行了验证,并且正在评估多种潜在材料。该指令影响从功率模块,智能功率ASIC到SMD封装和通孔封装的功率MOS-FET和IGBT在内的所有半导体器件类型,所有这些器件都包含含高温铅的焊料,直到RoHS豁免期满为止。一些IDM研究了四种基础材料技术:粘合剂,Ag烧结,混合材料和焊料,每种技术构成了批量生产的障碍。粘合剂可以使用当前的设备,但是价格昂贵并且导热率低。银烧结已显示出令人满意的温度循环结果,但成本高昂,并且需要开发新的设备和工艺。混合材料可以使用既定的设备套件,但价格昂贵,并且未经大量验证。焊接技术已经得到了广泛的发展,因为它最有可能为铅提供“嵌入式”解决方案。公司花了多年的时间来开发一种解决方案,该解决方案的性能类似,可以领导所有不同的应用程序。这些解决方案之一是Zn基合金,该合金已显示出可以在不使用昂贵的贵金属或资本支出的情况下为铅基材料提供几乎直接使用的解决方案的潜力。由于与铅的材料相似性,前几代焊料的开发最初是针对铋合金的。尽管铋合金在市场上可以买到,但它们有两个缺陷使它们无法被大量采用。第一个缺陷是导热系数低,仅达到12至17 W / m-K。第二个要求是在260°C下要承受3次回流焊的工艺要求。由于铋合金的熔化温度是255至275℃,因此它们不能满足回流工艺的要求。本文将重点研究用于替代高温焊料中铅的锌合金的开发。锌焊料克服了铋遇到的两个障碍,并提供了一种导热率高于100W / m-K,熔化温度高于300C的解决方案。另外,与替代解决方案相比,该焊料材料具有成本优势,同时与目前的铅焊料相比,具有更高的导热性和电阻率。锌合金的工艺窗口不如其铅焊料同类产品宽,需要大量的成分和工艺开发,并取决于器件的类型和用途,金属化要求。材料的发展使人们进一步了解了金属间化合物(IMC)的形成以及在使用裸铜引线框架和镀镍引线框架的可靠性评估期间对键合线的影响。按照建议的准则,锌基合金是在高温焊料中使用的铅的可接受替代品。
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