Self-Organized Ge Nanospherical Gate/SiO 2 /Si 0.15 Ge 0.85 -Nanosheet n-FETs Featuring High ON-OFF Drain Current Ratio

Po Hsiang Liao; Kang Ping Peng; Horng-Chih Lin; Thomas George; Pei-Wen Li

doi:10.1109/JEDS.2018.2876519

Self-Organized Ge Nanospherical Gate/SiO ₂ /Si _0.15 Ge _0.85 -Nanosheet n-FETs Featuring High ON-OFF Drain Current Ratio

Po Hsiang Liao, Kang Ping Peng, Horng-Chih Lin, Thomas George, Pei-Wen Li^*

^*此作品的通信作者

電子研究所

研究成果: Article › 同行評審

7 引文斯高帕斯（Scopus）

摘要

We reported experimental fabrication and characterization of Si _0.15 Ge _0.85 n-MOSFETs comprising a gate-stacking heterostructure of Ge-nanospherical gate/SiO ₂ /Si _0.15 Ge _0.85 -nanosheet on SOI (100) substrate in a self-organization approach. This unique gate-stacking heterostructure is simultaneously produced in a single oxidation step as a consequence of an exquisitely controlled dynamic balance between the concentrations of oxygen, Si, and Ge interstitials at 900 °C. Process-controlled tunability of nanospherical gate of 60-100 nm in diameter, gate oxide thickness of 3 nm, and Si _0.15 Ge _0.85 nanosheet with compressive strain of -2.5% was achieved. Superior gate modulation is evidenced by subthreshold slope of 150 mV/dec and I _ON I _OFF >5 × 10 ⁸ (I _OFF < 10 ^-6 μA μm and I _ON >500 μA μm ) measured at V _G = +1V , V _D = +1 V, and T = 80 K for our device with channel length of 75 nm.

原文	English
文章編號	8494752
頁（從 - 到）	57-61
頁數	5
期刊	IEEE Journal of the Electron Devices Society
卷	7
DOIs	https://doi.org/10.1109/JEDS.2018.2876519
出版狀態	Published - 1 1月 2019

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10.1109/JEDS.2018.2876519

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@article{102b1d61508d46a498334fc4782a1110,

title = "Self-Organized Ge Nanospherical Gate/SiO 2 /Si 0.15 Ge 0.85 -Nanosheet n-FETs Featuring High ON-OFF Drain Current Ratio",

abstract = " We reported experimental fabrication and characterization of Si 0.15 Ge 0.85 n-MOSFETs comprising a gate-stacking heterostructure of Ge-nanospherical gate/SiO 2 /Si 0.15 Ge 0.85 -nanosheet on SOI (100) substrate in a self-organization approach. This unique gate-stacking heterostructure is simultaneously produced in a single oxidation step as a consequence of an exquisitely controlled dynamic balance between the concentrations of oxygen, Si, and Ge interstitials at 900 °C. Process-controlled tunability of nanospherical gate of 60-100 nm in diameter, gate oxide thickness of 3 nm, and Si 0.15 Ge 0.85 nanosheet with compressive strain of -2.5% was achieved. Superior gate modulation is evidenced by subthreshold slope of 150 mV/dec and I ON I OFF >5 × 10 8 (I OFF < 10 -6 μA μm and I ON >500 μA μm ) measured at V G = +1V , V D = +1 V, and T = 80 K for our device with channel length of 75 nm. ",

keywords = "Ge-gate, SiGe nanosheet, junctionless FET, self organization",

author = "Liao, {Po Hsiang} and Peng, {Kang Ping} and Horng-Chih Lin and Thomas George and Pei-Wen Li",

year = "2019",

month = jan,

day = "1",

doi = "10.1109/JEDS.2018.2876519",

language = "English",

volume = "7",

pages = "57--61",

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

issn = "2168-6734",

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

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T1 - Self-Organized Ge Nanospherical Gate/SiO 2 /Si 0.15 Ge 0.85 -Nanosheet n-FETs Featuring High ON-OFF Drain Current Ratio

AU - Liao, Po Hsiang

AU - Peng, Kang Ping

AU - Lin, Horng-Chih

AU - George, Thomas

AU - Li, Pei-Wen

PY - 2019/1/1

Y1 - 2019/1/1

N2 - We reported experimental fabrication and characterization of Si 0.15 Ge 0.85 n-MOSFETs comprising a gate-stacking heterostructure of Ge-nanospherical gate/SiO 2 /Si 0.15 Ge 0.85 -nanosheet on SOI (100) substrate in a self-organization approach. This unique gate-stacking heterostructure is simultaneously produced in a single oxidation step as a consequence of an exquisitely controlled dynamic balance between the concentrations of oxygen, Si, and Ge interstitials at 900 °C. Process-controlled tunability of nanospherical gate of 60-100 nm in diameter, gate oxide thickness of 3 nm, and Si 0.15 Ge 0.85 nanosheet with compressive strain of -2.5% was achieved. Superior gate modulation is evidenced by subthreshold slope of 150 mV/dec and I ON I OFF >5 × 10 8 (I OFF < 10 -6 μA μm and I ON >500 μA μm ) measured at V G = +1V , V D = +1 V, and T = 80 K for our device with channel length of 75 nm.

AB - We reported experimental fabrication and characterization of Si 0.15 Ge 0.85 n-MOSFETs comprising a gate-stacking heterostructure of Ge-nanospherical gate/SiO 2 /Si 0.15 Ge 0.85 -nanosheet on SOI (100) substrate in a self-organization approach. This unique gate-stacking heterostructure is simultaneously produced in a single oxidation step as a consequence of an exquisitely controlled dynamic balance between the concentrations of oxygen, Si, and Ge interstitials at 900 °C. Process-controlled tunability of nanospherical gate of 60-100 nm in diameter, gate oxide thickness of 3 nm, and Si 0.15 Ge 0.85 nanosheet with compressive strain of -2.5% was achieved. Superior gate modulation is evidenced by subthreshold slope of 150 mV/dec and I ON I OFF >5 × 10 8 (I OFF < 10 -6 μA μm and I ON >500 μA μm ) measured at V G = +1V , V D = +1 V, and T = 80 K for our device with channel length of 75 nm.

KW - Ge-gate

KW - SiGe nanosheet

KW - junctionless FET

KW - self organization

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DO - 10.1109/JEDS.2018.2876519

M3 - Article

AN - SCOPUS:85055052863

VL - 7

SP - 57

EP - 61

JO - IEEE Journal of the Electron Devices Society

JF - IEEE Journal of the Electron Devices Society

SN - 2168-6734

M1 - 8494752

ER -

Self-Organized Ge Nanospherical Gate/SiO 2 /Si 0.15 Ge 0.85 -Nanosheet n-FETs Featuring High ON-OFF Drain Current Ratio

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Self-Organized Ge Nanospherical Gate/SiO ₂ /Si _0.15 Ge _0.85 -Nanosheet n-FETs Featuring High ON-OFF Drain Current Ratio