纳米级铜碳杂化互连的稳定性分析

B. Kumari, Rohit Sharma, Manodipan Sahoo
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引用次数: 2

摘要

铜碳(Cu-Carbon)混合互连是未来VLSI电路应用中极有前途的新候选,因此不仅需要分析其传播延迟,还应检查其稳定性,以巩固其作为现有互连配置替代方案的主张。在这项工作中,对最近提出的cu -碳杂化互连进行了稳定性分析,并与现有的替代杂化互连候选(即铜,铜-石墨烯杂化和铜-碳纳米管复合材料)进行了比较。本研究考虑7纳米技术节点的三线耦合互连系统,其尺寸参数采用IRDS路线图指南。铜碳混合互连的单位阶跃响应是最快的,因为它的切换延迟最低。cu -碳杂化的奈奎斯特图在离原点(- 1,0)最远的地方相交最稳定。串扰的影响导致铜互连的时域响应出现欠冲现象,但对铜碳杂化互连没有显著影响。结果表明,随着碳纳米管在铜碳杂化材料(Fcnt)中所占比例的增加,由于电阻的降低,带宽增加。此外,Fcnt = 0.8的Cu-Carbon是所有构型中最稳定的。我们得出结论,铜碳混合是所有替代互连配置中最稳定的候选者,声称它是近期VLSI应用的理想互连替代方案。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Stability Analysis of Nanoscale Copper-Carbon Hybrid Interconnects
Copper Carbon (Cu-Carbon) hybrid interconnect is a new and an extremely promising candidate for future VLSI circuit applications, so it needs to be analyzed for not only propagation delay but its stability should also be examined in order to consolidate its claim as an alternative to existing interconnect configurations. In this work, stability analysis of the recently proposed Cu-Carbon hybrid interconnect is performed and compared with existing alternate hybrid interconnect candidates (i.e. copper, copper-graphene hybrid and copper-carbon nanotube composite). A three-line coupled interconnect system for 7 nm technology node is considered in this study whose dimensional parameters are adopted as per the IRDS roadmap guidelines. The unit-step response of Cu-Carbon hybrid interconnect is steepest as compared to others because of its lowest switching delay. Cu-Carbon hybrid appears to be the most stable as its nyquist plot intersects farthest from the critical point (-1, j0) towards origin. The effect of crosstalk leads to undershoots as seen in the time domain response of copper interconnects, but it does not have any notable effect on Cu-Carbon hybrid interconnects. It is evident that as the fraction of carbon nanotube in Cu-Carbon hybrid (Fcnt) increases, bandwidth increases due to decrease in resistance. Also, Cu-Carbon with Fcnt = 0.8 is most stable amongst all configurations. We conclude that Cu-Carbon hybrid is the most stable candidate among all the alternative interconnect configurations, claiming it to be a desirable interconnect alternative for near-future VLSI applications.
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