J. Y. Dai, S. K. Loh, S. F. Tee, C. L. Tay, S. Ansari, E. Er, S. Redkar
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引用次数: 7
摘要
在亚微米多层金属化CMOS器件中,高电阻过孔和开孔触点是一个常见的问题,可能导致低产量和可靠性问题(Islamraja等人,1992)。经孔失效模式,如污染经孔、分层经孔和吹过的经孔触点已被详细记录(Hamanaka等人,1994;Chen et al., 1995)。与开孔接触相比,由于工艺裕度不足而导致的高电阻通孔更难隔离和物理表征。据报道,F污染会引起SRAM的阻力变化并导致定时问题(Perungulam et al., 2000)。然而,对于F通过Ti-TiN势垒金属层的扩散机制以及与势垒金属性能的关系以及可靠性测试中的失效机制的理解仍然有限。本文利用透射电镜研究了不同工艺分离步骤下F扩散引起的高通孔电阻失效机理。讨论了不同工艺制备的不同阻挡层的性能。
High resistance via induced by marginal barrier metal step coverage and F diffusion
In submicron multilevel metallization CMOS devices, high resistance vias and open via contacts are a common issue that can cause low yield and reliability problems (Islamraja et al., 1992). Via failure modes such as contaminated via, delaminated via and blown via contacts have been well documented (Hamanaka et al., 1994; Chen et al., 1995). Compared to the open via contact, a high resistance via due to insufficient process margin is more difficult to isolate and physically characterize. It has been reported that F contamination induces resistance variations and leads to timing issues in the SRAM (Perungulam et al., 2000). However, understanding of the F diffusion mechanism through the Ti-TiN barrier metal layer and the correlation with the barrier metal properties and thus the failure mechanism during reliability testing is still limited. In this paper, the failure mechanism of high via resistance caused by F diffusion was studied by transmission electron microscopy (TEM) at different process split steps. Properties of different barrier metal layers by different processes are also discussed.
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