C. Ko, T. Kuan, K. Zhang, G. Tsai, S. Seutter, C. Wu, T.J. Wang, C. Ye, H.W. Chen, C. Ge, K. Wu, W. Lee
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A novel CVD-SiBCN Low-K spacer technology for high-speed applications
State-of-the-art low-K spacer technology featuring novel CVD-SiBCN material is demonstrated for the first time. A significant 20% CMOS ring speed enhancement is demonstrated with SiBCN (K=5.2) spacer, compared to Si3N4 (K=7.5) spacer, due to reduced fringing capacitance and enhanced strain effects by spacer-PSS and CESL techniques. Electron mobility is improved by 6% for long channel NMOS transistor and gm,max is increased by 11% for short 35 nm physical gate length NMOS using a preferable spacer structure that is comprised of a low stress SiBCN spacer on thin SiO2 liner and a final 600degC rapid thermal post-anneal. Superior GIDL and better gate leakage is obtained because low permittivity SiBCN alleviates gate-fringing field effects (GF effects), and device reliability is not adversely impacted by this new process.
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