Investigation of Low-Temperature ICP-CVD µ -Si N-and P-Doped/Undoped Layers for Fully ICP-CVD Electronics

Olivier de Sagazan; Eva Bestelink; Nathalie Coulon; Andrei Uvarov; Radu A. Sporea; Emmanuel Jacques

doi:10.1109/TED.2024.3519061

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Investigation of Low-Temperature ICP-CVD µ -Si N-and P-Doped/Undoped Layers for Fully ICP-CVD Electronics

Journal article

Peer reviewed

Investigation of Low-Temperature ICP-CVD µ -Si N-and P-Doped/Undoped Layers for Fully ICP-CVD Electronics

Olivier de Sagazan, Eva Bestelink, Nathalie Coulon, Andrei Uvarov, Radu A. Sporea and Emmanuel Jacques

IEEE Transactions on Electron Devices, pp.1-7

25/12/2024

DOI: https://doi.org/10.1109/TED.2024.3519061

Abstract

Conductivity

Doping

inductively coupled plasma chemical vapor deposition (ICP-CVD)

Inductors

Insulators

low-temperature electronics

Monitoring

Plasma temperature

Plasmas

Silicon

Substrates

Thin film transistors

thin-film transistor (TFT) fabrication

Doped µ -Si flexible electronics

Low-temperature microcrystalline silicon ( μ -Si) has been realized in a Corial inductively coupled plasma chemical vapor deposition (ICP-CVD) system. Both doped and undoped μ -Si layers have been investigated in terms of resistivity and crystalline fraction. Following a μ -Si recipe using H 2 /Ar/SiH 4 mixture developed for plasma-enhanced chemical vapor deposition (PECVD), a technological transfer has been carried out in ICP-CVD. Some key parameters have been defined and a domain of use determined for N-type, P-type, and intrinsic layers. In the same reactor, nitride layers have also been deposited to perform gate insulator for thin-film transistors (TFTs). Finally, TFTs were fully realized by ICP-CVD and also electrically characterized, highlighting the interest of ICP-CVD for thin-film electronics. This demonstrates the great versatility of ICP-CVD technology applied to low-temperature electronic processes.

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Title: Investigation of Low-Temperature ICP-CVD µ -Si N-and P-Doped/Undoped Layers for Fully ICP-CVD Electronics
Creators: Olivier de Sagazan (Corresponding Author) - Université de Rennes
Eva Bestelink (Author) - University of Surrey, School of Computer Science and Electronic Engineering
Nathalie Coulon (Author) - Université de Rennes
Andrei Uvarov (Author) - Corial Company, Bernin, France
Radu A. Sporea (Author) - University of Surrey, School of Computer Science and Electronic Engineering
Emmanuel Jacques (Author) - Université de Rennes
Publication Details: IEEE Transactions on Electron Devices, pp.1-7
Publisher: Institute of Electrical and Electronics Engineers (IEEE); PISCATAWAY
Number of pages: 0
Publication Date: 25/12/2024
Date accepted for publication: 12/12/2024
Grants: AGELink, EP/R511791/1, Engineering and Physical Sciences Research Council (United Kingdom, Swindon) - EPSRC
EP/V002759/1, Engineering and Physical Sciences Research Council (United Kingdom, Swindon) - EPSRC
Grant note: EP/R511791/1; EP/V002759/1 / Engineering and Physical Sciences Research Council (EPSRC) (10.13039/501100000266)
Identifiers: 99954366302346; WOS:001385735600001
Copyright: © 2024 IEEE. All rights reserved, including rights for text and data mining, and training of artificial intelligence and similar technologies. Personal use is permitted, but republication/redistribution requires IEEE permission.
Academic Unit: School of Computer Science and Electronic Engineering
Language: English
Resource Type: Journal article

Investigation of Low-Temperature ICP-CVD µ -Si N-and P-Doped/Undoped Layers for Fully ICP-CVD Electronics

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