Buried Power Rail Integration With Si Finfets For Cmos Scaling Beyond The 5 Nm Node

A. Gupta,H. Mertens,Z. Tao,S. Demuynck,J. Bommels,G. Arutchelvan, K. Devriendt,O. Varela Pedreira,R. Ritzenthaler,S. Wang,D. Radisic,K. Kenis,L. Teugels,F. Sebaai, C. Lorant,N. Jourdan, B. T. Chan,H. Zahedmanesh,S. Subramanian,F. Schleicher,T. Hopf,A. Peter,N. Rassoul, H. Debruyn, I. Demonie, Y. Siew, T. Chiarella,B. Briggs,D. Zhou, E. Rosseel, A. De Keersgieter,E. Capogreco,E. Dentoni Litta, G. Boccardi, S. Baudot,G. Mannaert, N. Bontemps,A. Sepulveda, S. Mertens, M.-S. Kim, E. Dupuy, K. Vandersmissen, S. Paolillo,D. Yakimets,B. Chehab,P. Favia, C. Drijbooms, J. Cousserier,M. Jaysankar,F. Lazzarino,P. Morin,E. Sanchez, J. Mitard, C. Wilson, F. Holsteyns, Z. Tokei,N. Horiguchi

2020 IEEE SYMPOSIUM ON VLSI TECHNOLOGY（2020）

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摘要

Buried power rail (BPR) is a key scaling booster for CMOS extension beyond the 5 nm node. This paper demonstrates, for the first time, the integration of tungsten (W) BPR lines with Si finFETs. The characteristics of CMOS in close proximity to floating BPR are found to be similar to the characteristics of CMOS without BPR. Moreover, W-BPR interface with Ru via contact can withstand more than 320 h of electromigration (EM) stress at 4 MA/cm(2) and 330 degrees C, making Ru a candidate for via metallization to achieve low resistance contact strategy to BPR.

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关键词

low resistance contact strategy,metallization,electromigration stress,CMOS scaling,FinFET,buried power rail integration,W-BPR interface,tungsten BPR lines,key scaling booster,temperature 330.0 degC,Ru,W

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