Advanced Preclean Chamber for Ubm/Rdl Contact Resistance Improvement in Advanced Node Packaging Application

2020 International Wafer Level Packaging Conference (IWLPC) Pub Date : 2020-10-13 DOI:10.23919/IWLPC52010.2020.9375904

Kang Zhang, Kelvin Boh, Junqi Wei, T. Koh, Nuno Chen, Hannah Tang, Clinton Goh, Bridger Hoerner

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引用次数: 2

Abstract

Next-generation Under Bump Metallization (UBM) size reduction and increasing polymer thickness bring about thermomechanical benefits such as reduced low-k stress for advanced semiconductor packages. In addition, the adoption of fluorinated polymers provides low-k passivation which reduces signal delay and power consumption. However, these inflections at advanced nodes create new challenges for bump contact resistance ($\mathrm{R}_{\mathrm{C}}$) due to increased polymer outgassing and smaller via size. This paper describes an advanced pre-clean chamber and optimized pre-clean process condition developed to improve $\mathrm{R}_{\mathrm{C}}$ on various polymers. It is shown that the improved pre-clean efficiency results in significantly lower carbon, oxygen and fluorine contaminants at the Ti/Al interface, measured by TEM/EDX analysis. The $\mathrm{R}_{\mathrm{C}}$ values measured on a test vehicle with three-wire Kelvin test structures demonstrated a >60% lower $\mathrm{R}_{\mathrm{C}}$ and improved $\mathrm{R}_{\mathrm{C}}$ standard deviation. The new pre-clean chamber also enables higher throughput while maintaining a low wafer temperature for outgassing control.

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在先进节点封装应用中改善Ubm/Rdl接触电阻的先进预洁净室

下一代凹凸下金属化(UBM)的尺寸减小和聚合物厚度的增加为先进的半导体封装带来了诸如降低低k应力等热机械效益。此外，采用氟化聚合物可提供低k钝化，从而降低信号延迟和功耗。然而，由于聚合物放气增加和通孔尺寸减小，这些高级节点的弯曲对碰撞接触电阻($\ mathm {R}_{\ mathm {C}}$)提出了新的挑战。本文介绍了一种先进的预净室和优化的预净工艺条件，以改善各种聚合物的$\ mathm {R}_{\ mathm {C}}$。TEM/EDX分析表明，预清洁效率的提高显著降低了Ti/Al界面上的碳、氧和氟污染物。在采用三线开尔文测试结构的测试车上测量的$\ mathm {R}_{\ mathm {C}}$值显示$\ mathm {R}_{\ mathm {C}}$降低了约60%，并改善了$\ mathm {R}_{\ mathm {C}}$的标准差。新的预洁净室还可以实现更高的吞吐量，同时保持较低的晶圆温度，以进行排气控制。

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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2020 International Wafer Level Packaging Conference (IWLPC)

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