The study of electron mobility on ultra-scaled silicon nanosheet FET

Tongfei Liu; Ali Rezaei; Kaige Yang; Xuge Fan; Pranav Acharya; Vihar Georgiev; Asen Asenov; Jie Ding

doi:10.1088/1402-4896/ad56d9

The study of electron mobility on ultra-scaled silicon nanosheet FET

Tongfei Liu, Ali Rezaei, Kaige Yang, Xuge Fan, Pranav Acharya, Vihar Georgiev, Asen Asenov, Jie Ding

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

Abstract

The nanosheet FET (NSFET) is the successor to FinFET, and its mobility significantly affects device performance. In this paper, we investigate the impact of phonon (ph) and surface roughness (SR) scattering on the electron mobility of n-type silicon NSFETs. The effects of channel width, thickness, and doping concentrations on NSFETs' mobility are also analyzed. Non-Equilibrium Green's Function (NEGF) solver which incorporates scattering mechanisms using the self-energy formulation is employed. The mobility behavior in NSFETs is strongly affected by ph scattering and SR scattering. As for ultrathin nanosheets, severe mobility degradation is dominated by SR scattering. The mobility is slightly affected by the doping concentrations. Simulation results provide guidance to researchers and industry in understanding and predicting the variation of mobility under the trend of continuous scaling.

Original language	English
Article number	075410
Journal	Physica Scripta
Volume	99
Issue number	7
DOIs	https://doi.org/10.1088/1402-4896/ad56d9
Publication status	Published - 1 Jul 2024

Keywords

electron mobility
nanosheet FETs
phonon scattering
surface roughness scattering

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10.1088/1402-4896/ad56d9

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title = "The study of electron mobility on ultra-scaled silicon nanosheet FET",

abstract = "The nanosheet FET (NSFET) is the successor to FinFET, and its mobility significantly affects device performance. In this paper, we investigate the impact of phonon (ph) and surface roughness (SR) scattering on the electron mobility of n-type silicon NSFETs. The effects of channel width, thickness, and doping concentrations on NSFETs' mobility are also analyzed. Non-Equilibrium Green's Function (NEGF) solver which incorporates scattering mechanisms using the self-energy formulation is employed. The mobility behavior in NSFETs is strongly affected by ph scattering and SR scattering. As for ultrathin nanosheets, severe mobility degradation is dominated by SR scattering. The mobility is slightly affected by the doping concentrations. Simulation results provide guidance to researchers and industry in understanding and predicting the variation of mobility under the trend of continuous scaling.",

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AU - Yang, Kaige

AU - Fan, Xuge

AU - Acharya, Pranav

AU - Georgiev, Vihar

AU - Asenov, Asen

AU - Ding, Jie

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N2 - The nanosheet FET (NSFET) is the successor to FinFET, and its mobility significantly affects device performance. In this paper, we investigate the impact of phonon (ph) and surface roughness (SR) scattering on the electron mobility of n-type silicon NSFETs. The effects of channel width, thickness, and doping concentrations on NSFETs' mobility are also analyzed. Non-Equilibrium Green's Function (NEGF) solver which incorporates scattering mechanisms using the self-energy formulation is employed. The mobility behavior in NSFETs is strongly affected by ph scattering and SR scattering. As for ultrathin nanosheets, severe mobility degradation is dominated by SR scattering. The mobility is slightly affected by the doping concentrations. Simulation results provide guidance to researchers and industry in understanding and predicting the variation of mobility under the trend of continuous scaling.

AB - The nanosheet FET (NSFET) is the successor to FinFET, and its mobility significantly affects device performance. In this paper, we investigate the impact of phonon (ph) and surface roughness (SR) scattering on the electron mobility of n-type silicon NSFETs. The effects of channel width, thickness, and doping concentrations on NSFETs' mobility are also analyzed. Non-Equilibrium Green's Function (NEGF) solver which incorporates scattering mechanisms using the self-energy formulation is employed. The mobility behavior in NSFETs is strongly affected by ph scattering and SR scattering. As for ultrathin nanosheets, severe mobility degradation is dominated by SR scattering. The mobility is slightly affected by the doping concentrations. Simulation results provide guidance to researchers and industry in understanding and predicting the variation of mobility under the trend of continuous scaling.

KW - electron mobility

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The study of electron mobility on ultra-scaled silicon nanosheet FET

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