Self-aligned transparent-gate ITO/Germanium nanospheres/SiO2/SiGe-nanosheets photoMOSFETs on silicon nitride platform

Po Yu Hong; Bing Ju Lee; Rong Zong Yang; Horng Chih Lin; Pei Wen Li

doi:10.1109/JEDS.2022.3157741

Self-aligned transparent-gate ITO/Germanium nanospheres/SiO2/SiGe-nanosheets photoMOSFETs on silicon nitride platform

Po Yu Hong, Bing Ju Lee, Rong Zong Yang, Horng Chih Lin, Pei Wen Li

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摘要

We report experimental fabrication and characterization of photoMOSFETs with self-aligned gate-stacking heterostructures of indium-tin-oxide (ITO)/Ge nanospheres/SiO2-shell/Si1-xGex-nanosheets. Array of Ge-nanosphere/SiO2-shell/SiGe-nanosheet heterostructures was created in a self-organized, CMOS approach using the thermal oxidation of lithographically-patterned poly-Si0.85Ge0.15 nanopillars over buffer layers of Si3N4 on top of SOI substrates. With a polysilicon dummy-gate, source and drain self-align with the transparent ITO gate using a replacement-metal-gate process. Very high photocurrent gain, large photoresponsivity, as well as improved input capacitance and 3dB frequency were experimentally achievable in our photoMOSFETs. The pivotal roles of Ge-optical gate and SiGe-channel for large photoresponsivity and current gains were analyzed via numerical simulation.

原文	English
期刊	IEEE Journal of the Electron Devices Society
DOIs	https://doi.org/10.1109/JEDS.2022.3157741
出版狀態	Accepted/In press - 2022

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10.1109/JEDS.2022.3157741

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@article{51b383a6b4d14d039159bdebd8017688,

title = "Self-aligned transparent-gate ITO/Germanium nanospheres/SiO2/SiGe-nanosheets photoMOSFETs on silicon nitride platform",

abstract = "We report experimental fabrication and characterization of photoMOSFETs with self-aligned gate-stacking heterostructures of indium-tin-oxide (ITO)/Ge nanospheres/SiO2-shell/Si1-xGex-nanosheets. Array of Ge-nanosphere/SiO2-shell/SiGe-nanosheet heterostructures was created in a self-organized, CMOS approach using the thermal oxidation of lithographically-patterned poly-Si0.85Ge0.15 nanopillars over buffer layers of Si3N4 on top of SOI substrates. With a polysilicon dummy-gate, source and drain self-align with the transparent ITO gate using a replacement-metal-gate process. Very high photocurrent gain, large photoresponsivity, as well as improved input capacitance and 3dB frequency were experimentally achievable in our photoMOSFETs. The pivotal roles of Ge-optical gate and SiGe-channel for large photoresponsivity and current gains were analyzed via numerical simulation.",

keywords = "Germanium, germanium nanosphere, Indium tin oxide, Lighting, Logic gates, Nanoscale devices, photoconductive, photoMOSEFT, photovoltaic., Self-organization, SiGe, Silicon, Silicon germanium",

author = "Hong, {Po Yu} and Lee, {Bing Ju} and Yang, {Rong Zong} and Lin, {Horng Chih} and Li, {Pei Wen}",

note = "Publisher Copyright: Author",

year = "2022",

doi = "10.1109/JEDS.2022.3157741",

language = "English",

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

issn = "2168-6734",

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T1 - Self-aligned transparent-gate ITO/Germanium nanospheres/SiO2/SiGe-nanosheets photoMOSFETs on silicon nitride platform

AU - Hong, Po Yu

AU - Lee, Bing Ju

AU - Yang, Rong Zong

AU - Lin, Horng Chih

AU - Li, Pei Wen

N1 - Publisher Copyright: Author

PY - 2022

Y1 - 2022

N2 - We report experimental fabrication and characterization of photoMOSFETs with self-aligned gate-stacking heterostructures of indium-tin-oxide (ITO)/Ge nanospheres/SiO2-shell/Si1-xGex-nanosheets. Array of Ge-nanosphere/SiO2-shell/SiGe-nanosheet heterostructures was created in a self-organized, CMOS approach using the thermal oxidation of lithographically-patterned poly-Si0.85Ge0.15 nanopillars over buffer layers of Si3N4 on top of SOI substrates. With a polysilicon dummy-gate, source and drain self-align with the transparent ITO gate using a replacement-metal-gate process. Very high photocurrent gain, large photoresponsivity, as well as improved input capacitance and 3dB frequency were experimentally achievable in our photoMOSFETs. The pivotal roles of Ge-optical gate and SiGe-channel for large photoresponsivity and current gains were analyzed via numerical simulation.

AB - We report experimental fabrication and characterization of photoMOSFETs with self-aligned gate-stacking heterostructures of indium-tin-oxide (ITO)/Ge nanospheres/SiO2-shell/Si1-xGex-nanosheets. Array of Ge-nanosphere/SiO2-shell/SiGe-nanosheet heterostructures was created in a self-organized, CMOS approach using the thermal oxidation of lithographically-patterned poly-Si0.85Ge0.15 nanopillars over buffer layers of Si3N4 on top of SOI substrates. With a polysilicon dummy-gate, source and drain self-align with the transparent ITO gate using a replacement-metal-gate process. Very high photocurrent gain, large photoresponsivity, as well as improved input capacitance and 3dB frequency were experimentally achievable in our photoMOSFETs. The pivotal roles of Ge-optical gate and SiGe-channel for large photoresponsivity and current gains were analyzed via numerical simulation.

KW - Germanium

KW - germanium nanosphere

KW - Indium tin oxide

KW - Lighting

KW - Logic gates

KW - Nanoscale devices

KW - photoconductive

KW - photoMOSEFT

KW - photovoltaic.

KW - Self-organization

KW - SiGe

KW - Silicon

KW - Silicon germanium

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U2 - 10.1109/JEDS.2022.3157741

DO - 10.1109/JEDS.2022.3157741

M3 - Article

AN - SCOPUS:85126276787

SN - 2168-6734

JO - IEEE Journal of the Electron Devices Society

JF - IEEE Journal of the Electron Devices Society

ER -

Self-aligned transparent-gate ITO/Germanium nanospheres/SiO2/SiGe-nanosheets photoMOSFETs on silicon nitride platform

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