Title :
Atomic-scale modeling of source-to-drain tunneling in ultimate Schottky barrier double-gate MOSFETs
Author :
Bescond, M. ; Autran, J.L. ; Munteanu, D. ; Cavassilas, N. ; Lannoo, M.
Author_Institution :
Lab. Materiaux et Microelectronique de Provence, Maison des Technol., Toulon, France
Abstract :
The transport properties of single conduction channel Schottky barrier double-gate MOSFETs have been investigated by self-consistently solving the 2D Poisson equation with the Schrodinger equation, expressed in tight-binding using the Green´s function formalism. In this atomic-scale approach, the source-channel-drain axis of the transistor has been modeled by an atomic linear chain, sandwiched between two silicon oxides and gate electrodes. The dependence of source-to-drain tunneling with channel length and gate electrode workfunction as well as its impact on device characteristics have been carefully investigated. The results show that source-to-drain tunneling does set an ultimate scaling limit well below 10 nm.
Keywords :
Green´s function methods; MOSFET; Poisson equation; Schottky barriers; Schrodinger equation; semiconductor device models; tunnelling; work function; 10 nm; 2D Poisson equation; Green´s function formalism; MOSFET atomic-scale modeling; Schottky barrier double-gate MOSFET; Schrodinger equation; atomic linear chain; channel length; gate electrode workfunction; gate electrodes; silicon oxides; single conduction channel transport properties; source-to-drain tunneling; tight-binding; transistor source-channel-drain axis; ultimate scaling limit; Electrodes; Electrostatics; Green´s function methods; MOSFET circuits; Poisson equations; Reservoirs; Schottky barriers; Schrodinger equation; Silicon; Tunneling;
Conference_Titel :
European Solid-State Device Research, 2003. ESSDERC '03. 33rd Conference on
Conference_Location :
Estoril, Portugal
Print_ISBN :
0-7803-7999-3
DOI :
10.1109/ESSDERC.2003.1256897
