Title :
Silicon MOS transconductance scaling into the overshoot regime
Author :
Pinto, Mark R. ; Sangiorgi, Enrico ; Bude, Jeff
Author_Institution :
AT&T Bell Labs., Murray Hill, NJ, USA
Abstract :
Simulations incorporating velocity overshoot are used to derive the dependence of deep-submicrometer MOS transconductance on low-field mobility mu /sub eff/ and channel length L/sub ch/. In contract to strict velocity saturation, saturated transconductance departs from a strict mu /sub eff//L/sub ch/ dependence when overshoot is considered. Constraints on mu /sub eff/ derived from conventional scaling laws together with strong mu /sub eff/ dependencies in these regimes indicate the importance of low-field inversion layer control and optimization. Transconductance in saturation is shown to approach a well-defined limit for very high mu /sub eff/.<>
Keywords :
MOS integrated circuits; carrier mobility; elemental semiconductors; insulated gate field effect transistors; silicon; MOS transconductance scaling; Si; channel length; deep-submicrometer MOS; low-field inversion layer control; low-field mobility; nMOSFET; overshoot regime; saturated transconductance; velocity overshoot; Boltzmann equation; Carrier confinement; Constraint optimization; Doping; MOSFET circuits; Monte Carlo methods; Scattering; Silicon; Steady-state; Transconductance;
Journal_Title :
Electron Device Letters, IEEE
