Monte carlo simulation of electron transport properties in extremely thin SOI MOSFET's

Francisco Gâmiz; Juan A. Lôpez-Villanueva; Juan B. Roldân; Juan E. Carceller; Pedro Cartujo

doi:10.1109/16.669557

Monte carlo simulation of electron transport properties in extremely thin SOI MOSFET's

Francisco Gâmiz
, Juan A. Lôpez-Villanueva
, Juan B. Roldân
, Juan E. Carceller
, Pedro Cartujo

Research output: Contribution to journal › Article › peer-review

76 Scopus citations

Abstract

Electron mobility in extremely thin-film siliconon-insulator (SOI) MOSFET's has been simulated. A quantum mechanical calculation is implemented to evaluate the spatial and energy distribution of the electrons. Once the electron distribution is known, the effect of a drift electric field parallel to the Si-SiO₂ interfaces is considered. The Boltzmann transport equation is solved by the Monte Carlo method. The contribution of phonon, surface-roughness at both interfaces, and Coulomb scattering has been considered. The mobility decrease that appears experimentally in devices with a silicon film thickness under 20 nm is satisfactorily explained by an increase in phonon scattering as a consequence of the greater confinement of the electrons in the silicon film. -.

Original language	English
Pages (from-to)	1122-1126
Number of pages	5
Journal	IEEE Transactions on Electron Devices
Volume	45
Issue number	5
DOIs	https://doi.org/10.1109/16.669557
State	Published - 1 Dec 1998
Externally published	Yes

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abstract = "Electron mobility in extremely thin-film siliconon-insulator (SOI) MOSFET's has been simulated. A quantum mechanical calculation is implemented to evaluate the spatial and energy distribution of the electrons. Once the electron distribution is known, the effect of a drift electric field parallel to the Si-SiO2 interfaces is considered. The Boltzmann transport equation is solved by the Monte Carlo method. The contribution of phonon, surface-roughness at both interfaces, and Coulomb scattering has been considered. The mobility decrease that appears experimentally in devices with a silicon film thickness under 20 nm is satisfactorily explained by an increase in phonon scattering as a consequence of the greater confinement of the electrons in the silicon film. -.",

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T1 - Monte carlo simulation of electron transport properties in extremely thin SOI MOSFET's

AU - Gâmiz, Francisco

AU - Lôpez-Villanueva, Juan A.

AU - Roldân, Juan B.

AU - Carceller, Juan E.

AU - Cartujo, Pedro

PY - 1998/12/1

Y1 - 1998/12/1

N2 - Electron mobility in extremely thin-film siliconon-insulator (SOI) MOSFET's has been simulated. A quantum mechanical calculation is implemented to evaluate the spatial and energy distribution of the electrons. Once the electron distribution is known, the effect of a drift electric field parallel to the Si-SiO2 interfaces is considered. The Boltzmann transport equation is solved by the Monte Carlo method. The contribution of phonon, surface-roughness at both interfaces, and Coulomb scattering has been considered. The mobility decrease that appears experimentally in devices with a silicon film thickness under 20 nm is satisfactorily explained by an increase in phonon scattering as a consequence of the greater confinement of the electrons in the silicon film. -.

AB - Electron mobility in extremely thin-film siliconon-insulator (SOI) MOSFET's has been simulated. A quantum mechanical calculation is implemented to evaluate the spatial and energy distribution of the electrons. Once the electron distribution is known, the effect of a drift electric field parallel to the Si-SiO2 interfaces is considered. The Boltzmann transport equation is solved by the Monte Carlo method. The contribution of phonon, surface-roughness at both interfaces, and Coulomb scattering has been considered. The mobility decrease that appears experimentally in devices with a silicon film thickness under 20 nm is satisfactorily explained by an increase in phonon scattering as a consequence of the greater confinement of the electrons in the silicon film. -.

KW - MOS devices

KW - Silicon-on-insulator technology

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JO - IEEE Transactions on Electron Devices

JF - IEEE Transactions on Electron Devices

IS - 5

ER -

Monte carlo simulation of electron transport properties in extremely thin SOI MOSFET's

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