Title :
Channel Stress Modulation and Pattern Loading Effect Minimization of Milli-Second Super Anneal for Sub-65nm High Performance SiGe CMOS
Author :
Chen, Chien-Hao ; Nieh, C.F. ; Lin, D.W. ; Ku, K.C. ; Sheu, J.C. ; Yu, M.H. ; Wang, L.T. ; Lin, H.H. ; Chang, H. ; Lee, T.L. ; Goto, K. ; Diaz, Carlos H. ; Chen, S.C. ; Liang, M.S.
Author_Institution :
Res. & Dev., Taiwan Semicond. Manuf. Co. Ltd., Hsinchu
Abstract :
In this paper, we present an advanced integration approach using milli-second anneal technique to enhance device performance. In addition to enhanced poly-silicon activation, the device gain resulted from channel stress modulation, and retarded dopant diffusion can be obtained through process optimization including rapid-thermal anneal (RTA), capping layer, and milli-second anneal. More than 15% NMOS performance gain is demonstrated without undergoing milli-second-anneal-induced pattern loading effect and re-crystallization defect. No obvious stress relaxation and driving current degradation are observed in epi-SiGe PMOS. Moreover, the performance gain is increased while lowering the RTA temperature, suggesting that our proposed approach may open an alternative pathway for 45nm technology node and beyond
Keywords :
CMOS integrated circuits; Ge-Si alloys; laser beam annealing; nanotechnology; optimisation; rapid thermal annealing; 45 nm; RTA; SiGe; advanced integration; capping layer; channel stress modulation; enhanced polysilicon activation; high performance CMOS; millisecond super anneal; pattern loading effect minimization; process optimization; rapid-thermal annealing; retarded dopant diffusion; Absorption; Annealing; Compressive stress; Germanium silicon alloys; Optical films; Optical reflection; Performance gain; Silicon germanium; Temperature; Tensile stress;
Conference_Titel :
VLSI Technology, 2006. Digest of Technical Papers. 2006 Symposium on
Conference_Location :
Honolulu, HI
Print_ISBN :
1-4244-0005-8
DOI :
10.1109/VLSIT.2006.1705273
