Role of electrode potential difference between lead-free solder and copper base metal in wetting : Lead-free electronics packaging

T. Takemoto, Tatsuya Funaki
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引用次数: 36

Abstract

The role of the electrochemical reaction between solder and copper base metal in soldering flux was investigated in relation to wetting. The research includes the contact polarization between solder and base metal in soldering flux of RA type. The difference of electrode potential between solder and base metal in soldering flux plays an important role in removing the oxide film by contact polarization. It is concluded that the electrode potential of Sn-based lead-free solders should be significantly lower than copper to obtain good wettability, because the accelerated anodic dissolution of tin by contacting with the copper base metal enhances the wettability by the removal of tin oxide which is one of the stable oxide on base metal and solder. Sn-Pb has the adequate electrode potential to be effectively dissolved when contacted by copper. On the other hand, the electrode potential of Sn-3.5Ag is very close to copper: the condition gives extremely small contact current. The addition of less noble elements that can lower the electrode potential is effective to enhance the wettability of Sn-3.5Ag. Sn-Zn solder has extremely low electrode potential than a copper base metal; the situation excessively accelerates the preferential anodic dissolution of zinc resulting in the no dissolution of tin. The addition of lead to Sn-3.5Ag solder lowered the electrode potential, which increased the potential difference between solder and copper base metal, as a result the contact current between them was increased. The improved wettability is confirmed by adding lead to Sn-3.5Ag; all lead added solders showed a larger spread area, i.e., a smaller contact angle than Sn-3.5Ag after the spreading test. This work proposed the role of electrochemistry in wetting based on the potential difference between base metal and solder including the degree of contact corrosion current between them.
无铅焊料和铜基体金属在润湿过程中电极电位差的作用:无铅电子封装
研究了焊料与铜母材在助焊剂中的电化学反应与润湿的关系。对RA型焊剂中焊料与母材的接触极化进行了研究。焊剂中焊料与母材电极电位的差异对接触极化去除氧化膜起着重要作用。结果表明,锡基无铅钎料的电极电位应明显低于铜,以获得良好的润湿性,这是由于锡与铜母金属接触加速阳极溶解,从而使氧化锡(母金属和焊料上的稳定氧化物之一)脱除,从而提高了润湿性。Sn-Pb具有足够的电极电位,当与铜接触时可以有效溶解。另一方面,Sn-3.5Ag的电极电位非常接近铜:这种情况下接触电流非常小。在Sn-3.5Ag中加入能降低电极电位的低贵金属元素,可有效提高Sn-3.5Ag的润湿性。锡锌焊料具有极低的电极电位比铜基体金属;这种情况过度加速了锌的优先阳极溶解,导致锡不溶解。Sn-3.5Ag钎料中添加铅降低了电极电位,增大了钎料与铜母材之间的电位差,从而增大了两者之间的接触电流。Sn-3.5Ag中添加铅证实了润湿性的改善;与Sn-3.5Ag相比,所有添加铅的钎料在扩散试验后的扩散面积更大,即接触角更小。本文根据母材和焊料之间的电位差,包括它们之间的接触腐蚀电流的程度,提出了电化学在润湿过程中的作用。
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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