Extendibility of PVD barrier/seed for BEOL Cu metallization

Proceedings of the IEEE 2005 International Interconnect Technology Conference, 2005. Pub Date : 2005-06-06 DOI:10.1109/IITC.2005.1499954

C. Yang, D. Edelstein, L. Clevenger, A. Cowley, J. Gill, K. Chanda, A. Simon, T. Dalton, B. Agarwala, E. Cooney, D. Nguyen, T. Spooner, A. Stamper

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引用次数: 3

Abstract

The paper describes a new physical vapor deposition (PVD) metallization scheme that shows a better extendibility for future technology nodes as compared to the conventional scheme. In addition to reducing the thicknesses of both the diffusion barrier and the copper seed layer (Yang, C.-C. et al., MRS Adv. Metallization Conf., p.213, 2004), this new scheme also features a sacrificial process (also called barrier-first process) (Alers, G., IEEE Int. Interconnect Technology Conf., 2003), a via-punch through process (Edelstein, D. et al., IEEE Int. Reliability Physics Symp., p.316, 2004; Kuma, N. et al., MRS Adv. Metallization Conf, p.247, 2004) and a simultaneous preclean with a metal neutral deposition process (Yang et al., US Patent 6,784,105, 2004; Uzoh, C. et al., US Patents 5,930,669, 1999; 5,933,753, 1999; 6,429,519, 2002). Significant metal line and via contact resistance decrease was observed with equal or better reliability. The impact of a sputter etch integration scheme on electrical yield and reliability is also reported. The new sputter scheme decreases contact resistance at the via/interconnect interface and can offset the one resulting from dimension scaling and thus extends PVD metallization usefulness for future technologies.

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用于BEOL铜金属化的PVD屏障/种子的可扩展性

本文介绍了一种新的物理气相沉积(PVD)金属化方案，与传统方案相比，该方案对未来的技术节点具有更好的可扩展性。除了减少扩散屏障和铜种子层的厚度外(Yang, c . c . c .)。等人，MRS Adv. Metallization Conf.， p.213, 2004)，这个新方案还具有一个牺牲过程(也称为障碍优先过程)(Alers, G.， IEEE Int.)。互连技术会议，2003年)，通过穿孔过程(Edelstein, D. et al.， IEEE Int。可靠性物理研讨会。，第316页，2004;Kuma, N. etal .， MRS Adv. metalalization Conf, p.247, 2004)和同时预清洁与金属中性沉积工艺(Yang etal .， US Patent 6,784,105, 2004;等，美国专利5,930,669,1999;5933753年,1999年;6429519年,2002年)。观察到显著的金属线和通孔接触电阻降低，具有相同或更好的可靠性。此外，还报道了溅射蚀刻集成方案对发电效率和可靠性的影响。新的溅射方案降低了通孔/互连界面的接触电阻，可以抵消尺寸缩放造成的接触电阻，从而扩展了PVD金属化技术在未来技术中的用途。

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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Proceedings of the IEEE 2005 International Interconnect Technology Conference, 2005.

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