Self-Limited Low-Temperature Trimming and Fully Silicided S/D for Vertically Stacked Cantilever Gate-All-Around Poly-Si Junctionless Nanosheet Transistors

Chris Chun Chih Chung; Chun Ming Ko; Tien Sheng Chao

doi:10.1109/JEDS.2019.2940606

Self-Limited Low-Temperature Trimming and Fully Silicided S/D for Vertically Stacked Cantilever Gate-All-Around Poly-Si Junctionless Nanosheet Transistors

Chris Chun Chih Chung, Chun Ming Ko, Tien Sheng Chao^*

^*Corresponding author for this work

Department of Electrophysics

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

1 Scopus citations

Abstract

A self-limited low-temperature trimming process is demonstrated without surface morphology degradation. It shows great potential to control the trimming process with a large process window (400-900 s). Subthreshold characteristics are improved and I_off is drastically reduced (two orders of magnitude) with increasing trimming cycles. Full silicidation on the source/drain (FUSI-S/D) is performed to improve I_on. Surprisingly, after silicidation, both I_on and boldsymbolmu _mathrm FE shows degradation despite that the series resistance is improved. An ultrathin body junctionless (UTB-JL) device is fabricated to investigate the degradation cause by direct CV measurement on the device, which can give us an insight into the details of the change with the silicidation.

Original language	English
Article number	8843925
Pages (from-to)	959-963
Number of pages	5
Journal	IEEE Journal of the Electron Devices Society
Volume	7
Issue number	1
DOIs	https://doi.org/10.1109/JEDS.2019.2940606
State	Published - 2019

Keywords

fully silicided-S/D
junctionless
low-temperature trimming
monolithic 3D-ICs
nanosheet
poly-Si
Self-Limit
vertically stacked

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10.1109/JEDS.2019.2940606

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title = "Self-Limited Low-Temperature Trimming and Fully Silicided S/D for Vertically Stacked Cantilever Gate-All-Around Poly-Si Junctionless Nanosheet Transistors",

abstract = "A self-limited low-temperature trimming process is demonstrated without surface morphology degradation. It shows great potential to control the trimming process with a large process window (400-900 s). Subthreshold characteristics are improved and Ioff is drastically reduced (two orders of magnitude) with increasing trimming cycles. Full silicidation on the source/drain (FUSI-S/D) is performed to improve Ion. Surprisingly, after silicidation, both Ion and boldsymbolmu _mathrm FE shows degradation despite that the series resistance is improved. An ultrathin body junctionless (UTB-JL) device is fabricated to investigate the degradation cause by direct CV measurement on the device, which can give us an insight into the details of the change with the silicidation.",

keywords = "fully silicided-S/D, junctionless, low-temperature trimming, monolithic 3D-ICs, nanosheet, poly-Si, Self-Limit, vertically stacked",

author = "Chung, {Chris Chun Chih} and Ko, {Chun Ming} and Chao, {Tien Sheng}",

year = "2019",

doi = "10.1109/JEDS.2019.2940606",

language = "English",

volume = "7",

pages = "959--963",

journal = "IEEE Journal of the Electron Devices Society",

issn = "2168-6734",

publisher = "Institute of Electrical and Electronics Engineers Inc.",

number = "1",

}

Self-Limited Low-Temperature Trimming and Fully Silicided S/D for Vertically Stacked Cantilever Gate-All-Around Poly-Si Junctionless Nanosheet Transistors. / Chung, Chris Chun Chih; Ko, Chun Ming; Chao, Tien Sheng.
In: IEEE Journal of the Electron Devices Society, Vol. 7, No. 1, 8843925, 2019, p. 959-963.

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

TY - JOUR

T1 - Self-Limited Low-Temperature Trimming and Fully Silicided S/D for Vertically Stacked Cantilever Gate-All-Around Poly-Si Junctionless Nanosheet Transistors

AU - Chung, Chris Chun Chih

AU - Ko, Chun Ming

AU - Chao, Tien Sheng

PY - 2019

Y1 - 2019

N2 - A self-limited low-temperature trimming process is demonstrated without surface morphology degradation. It shows great potential to control the trimming process with a large process window (400-900 s). Subthreshold characteristics are improved and Ioff is drastically reduced (two orders of magnitude) with increasing trimming cycles. Full silicidation on the source/drain (FUSI-S/D) is performed to improve Ion. Surprisingly, after silicidation, both Ion and boldsymbolmu _mathrm FE shows degradation despite that the series resistance is improved. An ultrathin body junctionless (UTB-JL) device is fabricated to investigate the degradation cause by direct CV measurement on the device, which can give us an insight into the details of the change with the silicidation.

AB - A self-limited low-temperature trimming process is demonstrated without surface morphology degradation. It shows great potential to control the trimming process with a large process window (400-900 s). Subthreshold characteristics are improved and Ioff is drastically reduced (two orders of magnitude) with increasing trimming cycles. Full silicidation on the source/drain (FUSI-S/D) is performed to improve Ion. Surprisingly, after silicidation, both Ion and boldsymbolmu _mathrm FE shows degradation despite that the series resistance is improved. An ultrathin body junctionless (UTB-JL) device is fabricated to investigate the degradation cause by direct CV measurement on the device, which can give us an insight into the details of the change with the silicidation.

KW - fully silicided-S/D

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Self-Limited Low-Temperature Trimming and Fully Silicided S/D for Vertically Stacked Cantilever Gate-All-Around Poly-Si Junctionless Nanosheet Transistors

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Keywords

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