A full-band Monte Carlo model for silicon nanoscale devices with a quantum mechanical correction of the potential

Author

Tsuchiya, H. ; Fischer, B. ; Hess, K.

Author_Institution

Beckman Inst. for Adv. Sci. & Technol., Illinois Univ., Urbana, IL, USA

fYear

2000

fDate

10-13 Dec. 2000

Firstpage

283

Lastpage

286

Abstract

A new transport model for Si nanoscale devices is presented which consistently integrates a quantum mechanical correction of the potential into a full-band Monte Carlo model. This extends the framework of semiclassical particle simulations to the quantitative description of quantum mechanical effects. The model is applied to investigate quantum mechanical corrections to the drain induced barrier lowering typical for nanoscale MOSFETs. Our simulations show that the barrier lowering is enhanced in these devices.

Keywords

MOSFET; Monte Carlo methods; elemental semiconductors; nanotechnology; semiconductor device models; silicon; MOSFETs; Si; drain induced barrier lowering; full-band Monte Carlo model; nanoscale devices; quantum mechanical potential correction; semiclassical particle simulations; transport model; Boltzmann equation; Distribution functions; Effective mass; Electron devices; Electrostatics; Monte Carlo methods; Nanoscale devices; Quantum mechanics; Silicon; Virtual manufacturing;

fLanguage

English

Publisher

ieee

Conference_Titel

Electron Devices Meeting, 2000. IEDM '00. Technical Digest. International

Conference_Location

San Francisco, CA, USA

Print_ISBN

0-7803-6438-4

Type

conf

DOI

10.1109/IEDM.2000.904312

Filename

904312