Title :
pFET Vt control with HfO2/TiN/poly-Si gate stack using a lateral oxygenation process
Author :
Cartier, E. ; Steen, M. ; Linder, B.P. ; Ando, T. ; Iijima, R. ; Frank, M. ; Newbury, J.S. ; Kim, Y.H. ; McFeely, F.R. ; Copel, M. ; Haight, R. ; Choi, C. ; Callegari, A. ; Paruchuri, V.K. ; Narayanan, V.
Author_Institution :
IBM Semicond. R&D Center (SRDC), T.J. Watson Res. Center, Yorktown Heights, NY, USA
Abstract :
In this contribution, it is demonstrated that the threshold voltage, Vt, of a pFET can be modulated with lateral oxygenation of the HfO2/TiN/poly-Si gate stack from the S/D sidewall after spacer removal. This process can be applied to MIPS (Metal-inserted poly-Si) gate stacks after high-T S/D activation without any additional interfacial layer (IL) growth. Using lateral oxygenation, the pFET Vt can be lowerd by ~450 mV yielding a pFET with a Vt near band edge (within 250 mV). The shifter Vt is found to be stable during MOL/BEOL processing and the lateral oxygenation process does not degrade NBTI. Since Vt control is achieved with lateral oxygen diffusion, a channel length, L, dependence of Vt is observed. The L-dependence can be reduced by process optimization.
Keywords :
field effect transistors; optimisation; MIPS; S/D sidewall; lateral oxygenation process; metal-inserted poly-Si gate stacks; pFET; process optimization; spacer removal; Degradation; Hafnium oxide; Niobium compounds; Threshold voltage; Tin; Titanium compounds;
Conference_Titel :
VLSI Technology, 2009 Symposium on
Conference_Location :
Honolulu, HI
Print_ISBN :
978-1-4244-3308-7
