Title :
Dissipative transport in Multigate silicon nanowire transistors
Author :
Dehdashti, Nima ; Kranti, Abhinav ; Ferain, Isabelle ; Lee, Chi-Woo ; Yan, Ran ; Razavi, Pedram ; Yu, Ran ; Colinge, Jean-Pierre
Author_Institution :
Tyndall Nat. Inst., Cork, Ireland
Abstract :
Most device simulation packages performing quantum transport modeling in thin body Multigate silicon nanowire devices at nanometer scales neglect the electron-phonon interaction, assuming devices operate in the ballistic regime. Here we perform a detailed study on dissipative quantum transport in multigate silicon nanowire transistor including acoustic and optical phonons in detail using non-equilibrium Green´s function formalism in uncoupled mode-space approach. We find out that g-type phonons are the most important mechanisms contributing to current reduction in multigate nanowire both in subthreshold and above threshold region for silicon nanowire with 5 nm film thickness. This crucial rule of g-type phonons stay active even for gate lengths below 20 nm, which implies that ballistic models are inadequate to capture the device characteristics of nanometre devices.
Keywords :
Green´s function methods; elemental semiconductors; insulated gate field effect transistors; nanoelectronics; phonons; silicon; Si; acoustic phonon; ballistic models; device characteristics; dissipative quantum transport; g-type phonons; gate lengths; multigate silicon nanowire transistors; nanometre devices; nonequilibrium Green function formalism; optical phonon; size 5 nm; uncoupled mode-space approach; Acoustics; Mathematical model; Optical scattering; Phonons; Silicon; Transistors; acoustic phonons; dissipative quantum transport; non-equilibrium Green´s function; optical phonons; single band effective mass;
Conference_Titel :
Simulation of Semiconductor Processes and Devices (SISPAD), 2010 International Conference on
Conference_Location :
Bologna
Print_ISBN :
978-1-4244-7701-2
Electronic_ISBN :
1946-1569
DOI :
10.1109/SISPAD.2010.5604559
