Title :
Alternative approaches for high-k/metal gate CMOS: Low temperature process (gate last) and SiGe channel
Author :
Park, C.S. ; Hussain, M.M. ; Tateiwa, K. ; Huang, J. ; Lin, J. ; Ngai, T. ; Lian, S. ; Rader, K. ; Taylor, B. ; Kirsch, P.D. ; Jammy, R.
Abstract :
A comprehensive materials set has been fabricated and characterized to address the challenging issues in both gate first and gate last HK/MG CMOS. Specifically, metal gate thermal budget and channel composition are shown to be effective methods to engineer pMetal effective work function for gate last and gate first, respectively. Low temperature processing has resulted in low nMOS Vfb and high pMOS Vfb (ΔEWF=~900mV) without the Vfb roll-off typically observed for gate first pMetals. Gate first high-k/metal gate CMOS has also been demonstrated using dual channel, single metal gate. Excellent pFET Ion-Ioff characteristics, 500 μA/μm at 1nA/μm for Vdd=1V have been achieved without additional strain engineering owing to: [i] optimized SiGe thickness, [ii] optimized Ge concentration, [iii] reduced Rext, [iv] minimized Coulomb scattering at short channel, and [v] scaled gate oxide thickness.
Keywords :
CMOS integrated circuits; Ge-Si alloys; high-k dielectric thin films; Coulomb scattering; SiGe; channel composition; dual channel; gate first; gate last; high pMOS; high-k-metal gate CMOS; low nMOS; low temperature process; metal gate thermal budget; scaled gate oxide thickness; single metal gate; voltage 1 V; CMOS process; Capacitive sensors; Germanium silicon alloys; High K dielectric materials; High-K gate dielectrics; MOS devices; Scattering; Silicon germanium; Temperature; Thermal engineering;
Conference_Titel :
VLSI Technology Systems and Applications (VLSI-TSA), 2010 International Symposium on
Conference_Location :
Hsinchu
Print_ISBN :
978-1-4244-5063-3
Electronic_ISBN :
1524-766X
DOI :
10.1109/VTSA.2010.5488940
