Title :
Device scaling model for bulk FinFETs
Author :
Medury, A. ; Mercha, K. ; Ritzenthaler, R. ; De Keersgieter, A. ; Chiarella, T. ; Collaert, N. ; Bhat, N. ; Bhat, K.N.
Author_Institution :
CENSE, Indian Inst. of Sci., Bangalore, India
Abstract :
FinFETs are being considered as an attractive alternative to enable further CMOS Scaling. In this paper, a device scaling model for the electrostatics of bulk FinFETs is presented. Device parameters such as subthreshold slope (SS), threshold voltage (Vth), off-state current (IOFF)>; drain-induced-barrier lowering (DIBL) are modeled showing good agreement with TCAD and experimental results. Besides predicting the effects of technology scaling, this model provides good insight in terms of device design. By accounting for the effects of fin geometry variation and the drain voltage (Vd) on the effective fin doping (Na(ef)), the present work is very useful in determining Na(ff)) for low Vth, standard Vth and high Vth applications. Based on this model, it is also possible to determine the geometrical parameters required to achieve SS = 80 mV/dec, DIBL = 50 mV/V.
Keywords :
MOSFET; CMOS scaling; bulk FinFET; device design; device scaling model; drain voltage; drain-induced-barrier lowering; electrostatics; fin doping; fin geometry variation; off-state current; subthreshold slope; technology scaling; threshold voltage; CMOS integrated circuits; Doping; Electrostatics; Equations; FinFETs; Mathematical model; Semiconductor device modeling; Bulk FinFETs; Electrostatics; Predictive Device Scaling Model;
Conference_Titel :
Ultimate Integration on Silicon (ULIS), 2012 13th International Conference on
Conference_Location :
Grenoble
Print_ISBN :
978-1-4673-0191-6
Electronic_ISBN :
978-1-4673-0190-9
DOI :
10.1109/ULIS.2012.6193370
