Title :
Mechanistic understanding of mobility degradation on gate-last ZrO2 with medium thermal budget annealing
Author :
Ngai, T. ; Clark, R.D. ; Veksler, Dekel ; Matthews, K. ; Bersch, E. ; Gilmer, D.C. ; Bersuker, Gennadi ; Hill, Richard ; Hobbs, Chris ; Tapily, K. ; Wajda, C.S. ; Consiglio, S. ; Burroughs, Tricia ; Vivekanand, S. ; Kaushik, Vijender ; Leusink, G.J. ; Kir
Author_Institution :
SEMATECH, Albany, NY, USA
Abstract :
In this paper, we provide a mechanistic understanding of mobility degradation of gate-last ZrO2 subjected to medium thermal budget annealing. We find that high-k post deposition anneal (PDA) even at modest temperatures can improve the interfacial layer (IL) and bulk oxide, but mobility suffers. The mechanism for this mobility degradation is the enhanced remote Coulomb scattering from nonstoichiometric ZrOx region near the IL. The high-k PDA, even at moderate temperature, enables oxygen gettering of the IL and deprives oxygen from ZrO2 near the IL, which results in the accumulation of defects/traps in the region near ZrO2/IL interface. This enhances remote Coulomb scattering due to the high concentration of oxide traps and their close proximity to the conductance channel. Consequently, mobility is degraded even though IL and bulk oxide are improved.
Keywords :
MOSFET; high-k dielectric thin films; rapid thermal annealing; zirconium compounds; IL; ZrO2; bulk oxide; conductance channel; defect-trap accumulation; enhanced remote Coulomb scattering; gate-last process; high-k PDA; high-k post deposition anneal; interfacial layer; medium thermal budget annealing; mobility degradation; n-channel MOSFETs; nonstoichiometric region; oxide trap concentration; p-channel MOSFETs; Annealing; Degradation; Films; High K dielectric materials; Logic gates; MOSFET; Thermal degradation;
Conference_Titel :
VLSI Technology, Systems and Application (VLSI-TSA), Proceedings of Technical Program - 2014 International Symposium on
Conference_Location :
Hsinchu
DOI :
10.1109/VLSI-TSA.2014.6839649
