Title :
Simulation of quantum transport in an ultra-small SOI MOSFET
Author :
Gilbert, M.J. ; Ferry, D.K.
Author_Institution :
Dept. of Electr. Eng. & Center for Solid Stare Electron. Res., Arizona State Univ., Tempe, AZ, USA
Abstract :
Industry predictions estimate that, within a few years, semiconductor devices with active regions of less than 10 nm in length will be in production. It is well known that the active regions in these devices are smaller than the relative phase coherence lengths, and quantum transport will govern the operation of these devices. With the advent of tri-gate and quantum wire devices, 2D transport simulations become inadequate as the third dimension (width) must be included to account for the underlying physics present in the problem. Here, we present results of an efficient 3D, self-consistent quantum transport simulation applied to an ultra-small SOI MOSFET. We find that the transition between a wide source contact and a discretely doped, narrow channel sets up a resonant tunneling situation in which the channel becomes fully populated and then dissipates as the gate voltage is swept.
Keywords :
MOSFET; quantum gates; semiconductor quantum wires; silicon-on-insulator; 2D transport simulation; 3D quantum transport simulation; active region; gate voltage; narrow channel; quantum wire device; resonant tunneling; semiconductor devices; tri-gate device; ultra-small SOI MOSFET; Computational modeling; Electronics industry; Industrial electronics; MOSFET circuits; Production; Resonant tunneling devices; Semiconductor devices; Semiconductor films; Solids; State estimation;
Conference_Titel :
Solid-State and Integrated Circuits Technology, 2004. Proceedings. 7th International Conference on
Print_ISBN :
0-7803-8511-X
DOI :
10.1109/ICSICT.2004.1436667
