Thermal stability study of Si cap/ultrathin Ge/Si and strained Si/Si 1-xGex/Si nMOSFETs with HfO2 gate dielectric

C. C. Yeo; B. J. Cho; M. H. Lee; C. W. Liu; K. J. Choi; T. W. Lee

doi:10.1088/0268-1242/21/5/017

Thermal stability study of Si cap/ultrathin Ge/Si and strained Si/Si _1-xGe_x/Si nMOSFETs with HfO₂ gate dielectric

C. C. Yeo^*, B. J. Cho, M. H. Lee, C. W. Liu, K. J. Choi, T. W. Lee

^*Corresponding author for this work

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

1 Citation (Scopus)

Abstract

The thermal stabilities of MOSFETs with high-K gate dielectric on both Si/ultrathin Ge/Si (SGS) and strained Si on relaxed Si_1- _xGe_x (SS) substrates are studied. Though an initial drivability enhancement of 29% is shown for the SGS nMOSFET, annealing at 750 °C has resulted in drastic degradation in its drivability, lowering its I_d beyond that of the Si nMOSFETs by 52%. Despite lowering in the junction leakage current, Ge diffusion to the near surface region, indicated by V_th and surface roughness change, degrades the SGS device performance significantly. For the SS nMOSFET, drivability varies with Ge content, whereby a maximum of 86% improvement over that of the Si nMOSFET is observed for 30% Ge. In contrast to the SGS nMOSFET, the SS nMOSFET is able to retain its I _d improvement, even after annealing at 950 °C, as the in-plane tensile strain is preserved. Ge diffusion to the surface does not affect the device significantly, as the strained Si thickness is about 10 nm compared to a Si cap thickness of only 1.5 nm for the SGS substrate.

Original language	English
Pages (from-to)	665-669
Number of pages	5
Journal	Semiconductor Science and Technology
Volume	21
Issue number	5
DOIs	https://doi.org/10.1088/0268-1242/21/5/017
Publication status	Published - 2006 May 1
Externally published	Yes

ASJC Scopus subject areas

Electronic, Optical and Magnetic Materials
Condensed Matter Physics
Electrical and Electronic Engineering
Materials Chemistry

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title = "Thermal stability study of Si cap/ultrathin Ge/Si and strained Si/Si 1-xGex/Si nMOSFETs with HfO2 gate dielectric",

abstract = "The thermal stabilities of MOSFETs with high-K gate dielectric on both Si/ultrathin Ge/Si (SGS) and strained Si on relaxed Si1- xGex (SS) substrates are studied. Though an initial drivability enhancement of 29% is shown for the SGS nMOSFET, annealing at 750 °C has resulted in drastic degradation in its drivability, lowering its Id beyond that of the Si nMOSFETs by 52%. Despite lowering in the junction leakage current, Ge diffusion to the near surface region, indicated by Vth and surface roughness change, degrades the SGS device performance significantly. For the SS nMOSFET, drivability varies with Ge content, whereby a maximum of 86% improvement over that of the Si nMOSFET is observed for 30% Ge. In contrast to the SGS nMOSFET, the SS nMOSFET is able to retain its I d improvement, even after annealing at 950 °C, as the in-plane tensile strain is preserved. Ge diffusion to the surface does not affect the device significantly, as the strained Si thickness is about 10 nm compared to a Si cap thickness of only 1.5 nm for the SGS substrate.",

author = "Yeo, {C. C.} and Cho, {B. J.} and Lee, {M. H.} and Liu, {C. W.} and Choi, {K. J.} and Lee, {T. W.}",

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AU - Yeo, C. C.

AU - Cho, B. J.

AU - Lee, M. H.

AU - Liu, C. W.

AU - Choi, K. J.

AU - Lee, T. W.

PY - 2006/5/1

Y1 - 2006/5/1

N2 - The thermal stabilities of MOSFETs with high-K gate dielectric on both Si/ultrathin Ge/Si (SGS) and strained Si on relaxed Si1- xGex (SS) substrates are studied. Though an initial drivability enhancement of 29% is shown for the SGS nMOSFET, annealing at 750 °C has resulted in drastic degradation in its drivability, lowering its Id beyond that of the Si nMOSFETs by 52%. Despite lowering in the junction leakage current, Ge diffusion to the near surface region, indicated by Vth and surface roughness change, degrades the SGS device performance significantly. For the SS nMOSFET, drivability varies with Ge content, whereby a maximum of 86% improvement over that of the Si nMOSFET is observed for 30% Ge. In contrast to the SGS nMOSFET, the SS nMOSFET is able to retain its I d improvement, even after annealing at 950 °C, as the in-plane tensile strain is preserved. Ge diffusion to the surface does not affect the device significantly, as the strained Si thickness is about 10 nm compared to a Si cap thickness of only 1.5 nm for the SGS substrate.

AB - The thermal stabilities of MOSFETs with high-K gate dielectric on both Si/ultrathin Ge/Si (SGS) and strained Si on relaxed Si1- xGex (SS) substrates are studied. Though an initial drivability enhancement of 29% is shown for the SGS nMOSFET, annealing at 750 °C has resulted in drastic degradation in its drivability, lowering its Id beyond that of the Si nMOSFETs by 52%. Despite lowering in the junction leakage current, Ge diffusion to the near surface region, indicated by Vth and surface roughness change, degrades the SGS device performance significantly. For the SS nMOSFET, drivability varies with Ge content, whereby a maximum of 86% improvement over that of the Si nMOSFET is observed for 30% Ge. In contrast to the SGS nMOSFET, the SS nMOSFET is able to retain its I d improvement, even after annealing at 950 °C, as the in-plane tensile strain is preserved. Ge diffusion to the surface does not affect the device significantly, as the strained Si thickness is about 10 nm compared to a Si cap thickness of only 1.5 nm for the SGS substrate.

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Thermal stability study of Si cap/ultrathin Ge/Si and strained Si/Si _1-xGe_x/Si nMOSFETs with HfO₂ gate dielectric

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