Electron transport properties of quantized silicon carbide inversion layers

J. B. Roldán; F. Gámiz; J. A. López Villanueva; P. Cartujo

doi:10.1007/s11664-997-0151-3

Electron transport properties of quantized silicon carbide inversion layers

J. B. Roldán
, F. Gámiz
, J. A. López Villanueva
, P. Cartujo

Producción científica: Contribución a una revista › Artículo › revisión exhaustiva

14 Citas (Scopus)

Resumen

Electron transport properties in SiC quantized inversion layers have been studied by means of a Monte Carlo procedure. It has been observed that the contribution of polar-optical phonon scattering produces a significant influence of the effective-electric field on the high longitudinal field transport regime, this being the main difference of SiC with respect to standard Si inversion layers. The energy- and momentum-relaxation times have been calculated and the results suggest that electron velocity overshoot effects are less important than in Si metal-oxide semiconductor field effect transistors. The electron mobility is not very different from their silicon counterparts, but the saturation velocity is higher.

Idioma original	Inglés
Páginas (desde-hasta)	203-207
Número de páginas	5
Publicación	Journal of Electronic Materials
Volumen	26
N.º	3
DOI	https://doi.org/10.1007/s11664-997-0151-3
Estado	Publicada - 1 ene. 1997
Publicado de forma externa	Sí

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title = "Electron transport properties of quantized silicon carbide inversion layers",

abstract = "Electron transport properties in SiC quantized inversion layers have been studied by means of a Monte Carlo procedure. It has been observed that the contribution of polar-optical phonon scattering produces a significant influence of the effective-electric field on the high longitudinal field transport regime, this being the main difference of SiC with respect to standard Si inversion layers. The energy- and momentum-relaxation times have been calculated and the results suggest that electron velocity overshoot effects are less important than in Si metal-oxide semiconductor field effect transistors. The electron mobility is not very different from their silicon counterparts, but the saturation velocity is higher.",

keywords = "Electron mobility, High field transport properties, Polar-optical phonon scattering, Silicon carbide inversion layer",

author = "Rold{\'a}n, \{J. B.\} and F. G{\'a}miz and \{L{\'o}pez Villanueva\}, \{J. A.\} and P. Cartujo",

year = "1997",

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doi = "10.1007/s11664-997-0151-3",

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T1 - Electron transport properties of quantized silicon carbide inversion layers

AU - Roldán, J. B.

AU - Gámiz, F.

AU - López Villanueva, J. A.

AU - Cartujo, P.

PY - 1997/1/1

Y1 - 1997/1/1

N2 - Electron transport properties in SiC quantized inversion layers have been studied by means of a Monte Carlo procedure. It has been observed that the contribution of polar-optical phonon scattering produces a significant influence of the effective-electric field on the high longitudinal field transport regime, this being the main difference of SiC with respect to standard Si inversion layers. The energy- and momentum-relaxation times have been calculated and the results suggest that electron velocity overshoot effects are less important than in Si metal-oxide semiconductor field effect transistors. The electron mobility is not very different from their silicon counterparts, but the saturation velocity is higher.

AB - Electron transport properties in SiC quantized inversion layers have been studied by means of a Monte Carlo procedure. It has been observed that the contribution of polar-optical phonon scattering produces a significant influence of the effective-electric field on the high longitudinal field transport regime, this being the main difference of SiC with respect to standard Si inversion layers. The energy- and momentum-relaxation times have been calculated and the results suggest that electron velocity overshoot effects are less important than in Si metal-oxide semiconductor field effect transistors. The electron mobility is not very different from their silicon counterparts, but the saturation velocity is higher.

KW - Electron mobility

KW - High field transport properties

KW - Polar-optical phonon scattering

KW - Silicon carbide inversion layer

UR - https://www.scopus.com/pages/publications/3743072636

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SP - 203

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JO - Journal of Electronic Materials

JF - Journal of Electronic Materials

IS - 3

ER -

Electron transport properties of quantized silicon carbide inversion layers

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