Applicability of Macroscopic Transport Models to Decananometer MOSFETs

Author

Vasicek, Martin ; Cervenka, Johann ; Esseni, David ; Palestri, Pierpaolo ; Grasser, Tibor

Author_Institution

Wolfgang Pauli Inst., Univ. of Vienna, Vienna, Austria

Volume

59

Issue

3

fYear

2012

fDate

3/1/2012 12:00:00 AM

Firstpage

639

Lastpage

646

Abstract

We perform a comparative study of various macroscopic transport models against multisubband Monte Carlo (MC) device simulations for decananometer MOSFETs in an ultra-thin body double-gate realization. The transport parameters of the macroscopic models are taken from homogeneous subband MC simulations, thereby implicitly taking surface roughness and quantization effects into account. Our results demonstrate that the drift-diffusion (DD) model predicts accurate drain currents down to channel lengths of about 40 nm but fails to predict the transit frequency below 80 nm. The energy-transport (ET) model, on the other hand, gives good drain currents and transit frequencies down to 80 nm, whereas below 80 nm, the error rapidly increases. The six moments model follows the results of MC simulations down to 30 nm and outperforms the DD and the ET models.

Keywords

MOSFET; Monte Carlo methods; nanoelectronics; semiconductor device models; surface roughness; transport processes; decananometer MOSFET; drain current; drift diffusion model; energy transport model; macroscopic transport model; multisubband Monte Carlo device simulation; quantization effect; surface roughness; ultra thin body double gate realization; Computational modeling; Equations; Heating; MOSFETs; Mathematical model; Scattering; Surface roughness; Drift-diffusion (DD) model; energy-transport (ET) model; higher order transport models; quantization; six moments (SM) model; subband Monte Carlo (SMC); surface roughness scattering;

fLanguage

English

Journal_Title

Electron Devices, IEEE Transactions on

Publisher

ieee

ISSN

0018-9383

Type

jour

DOI

10.1109/TED.2011.2181177

Filename

6140555