(111)纳米孪晶Cu对微尺度纳米孪晶Cu/Sn/Ni互连中溶解行为和界面反应的影响

M.L. Huang, S. Wang, Jie Ren
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引用次数: 1

摘要

以(111)纳米孪晶Cu (nt-Cu)代替普通多晶Cu作为碰撞金属化(UBM),研究了微尺度Cu/Sn (100 μm)/Ni型互连线的液固界面反应,并研究了不同时间焊接反应后微尺度互连线的抗剪强度和电阻。在250℃的焊接反应中,(111)nt-Cu UBM的溶解速率(0.06 μm/min)仅为多晶Cu UBM (0.18 μm/min)的三分之一,并且有效抑制了nt-Cu/Sn/Ni互连中界面IMCs的生长。用浓度梯度控制(CGC)界面反应模型解释了Cu/Sn/Ni型互连中界面IMCs的生长机理。即使在焊接反应60 min后,以nt-Cu作为UBMs时,Cu/Sn/Ni型互连的抗剪强度仅下降12.3%,而以普通多晶Cu作为UBMs时,其抗剪强度下降28.1%;当nt-Cu作为UBMs时,Cu/Sn/Ni互连的电阻只增加了3.3%,而当普通多晶Cu作为UBMs时,电阻增加了20.3%。本研究将为新开发的(111)纳米孪晶Cu UBMs在先进封装和微尺度互连设计中的应用提供实验依据和理论指导。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Role of (111) nanotwinned Cu on dissolution behavior and interfacial reaction in micro-scale nanotwinned Cu/Sn/Ni interconnects
The liquid-solid (L-S) interfacial reaction of the micro-scale Cu/Sn (100 μm)/Ni type interconnect was investigated with (111) nanotwinned Cu (nt-Cu) acting as under bump metallization (UBM) instead of common polycrystalline Cu, and the shear strength and the electric resistance of micro-scale interconnects after soldering reaction for various times were also studied. The dissolution rate of (111) nt-Cu UBM (0.06 μm/min) during the soldering reaction at 250 oC was only one third of that of polycrystalline Cu UBM (0.18 μm/min), and the growth of interfacial IMCs in nt-Cu/Sn/Ni interconnects was effectively suppressed. The growth mechanism on interfacial IMCs in the Cu/Sn/Ni type interconnect was explained by the concentration gradient control (CGC) interfacial reaction model. Even after soldering reaction for 60 min, the shear strength of the Cu/Sn/Ni type interconnect dropped by only 12.3 % if nt-Cu acts as UBMs, compared to 28.1 % if common polycrystalline Cu acts as UBMs; the electric resistance of the Cu/Sn/Ni interconnect increased only 3.3 % if nt-Cu acts as UBMs, compared to 20.3 % if common polycrystalline Cu acts as UBMs. This study will provide the experimental basis and theoretical guidance for the application of newly developed (111) nanotwinned Cu UBMs in advanced packaging and the design of micro-scale interconnects.
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