Technology challenges and enablers to extend Cu metallization to beyond 7 nm node

2019 Symposium on VLSI Technology Pub Date : 2019-06-09 DOI:10.23919/VLSIT.2019.8776573

T. Nogami, H. Huang, H. Shobha, R. Patlolla, J. Kelly, C. Penny, C. Hu, D. Sil, S. DeVries, J. Lee, S. Nguyen, L. Jiang, J. Demarest, J. Li, G. Lian, M. Ali, P. Bhosale, N. Lanzillo, K. Motoyama, S. Lian, T. Standaert, G. Bonilla, D. Edelstein, B. Haran

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引用次数: 1

Abstract

Electromigration (EM) and TDDB reliability of Cu interconnects with a barrier/wetting layer as thin as 2 nm employing a PVD-reflowed through-Co self-forming barrier (tCoSFB) is demonstrated to meet the required specifications for 7 nm BEOL. The resulting Cu EM lifetime is 2000X longer than Cu interconnects with a standard scaled barrier/wetting layer. This tCoSFB Cu EM and TDDB reliability performance were equivalent to pure Co metal interconnects, but with a 50% lower line resistance even down to 30 nm pitch dimensions. However, the annealing process for PVD-reflow Cu seed that enhances EM reliability caused Cu agglomeration at dual damascene line-end vias, leading to poor via-chain yield. Resolving this geometry-sensitive via-fill problem was identified as key to extending Cu manufacturability to 7 nm and beyond. We propose, and show preliminary data, for Cu/tCoSFB metallization with CVD Co via pre-fill as potential solution.

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将铜金属化扩展到7nm以上节点的技术挑战和推动因素

采用pvd回流通过co自形成势垒(tCoSFB)的铜互连的电迁移(EM)和TDDB可靠性达到了7纳米BEOL的要求规格。由此产生的Cu EM寿命比具有标准鳞片屏障/润湿层的Cu互连长2000倍。这种tCoSFB Cu EM和TDDB的可靠性性能相当于纯钴金属互连，但即使在30nm间距尺寸下，线路电阻也降低了50%。然而，提高电磁可靠性的pvd -回流铜籽的退火工艺导致铜在双damascene线端过孔处聚集，导致过孔链产率较差。解决这种几何敏感的过孔填充问题被认为是将铜的可制造性扩展到7纳米及以上的关键。我们提出并展示了通过预填充的CVD Co作为潜在解决方案的Cu/tCoSFB金属化的初步数据。

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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2019 Symposium on VLSI Technology

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