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@proceedings{1801303,
author = {Sihelník, Slavomír and Krumpolec, Richard and Homola, Tomáš and Feng, Jianyu and Kosová, Eva and Jamaati Kenari, Ali and Stupavská, Monika and Kelar, Jakub and Černák, Mirko and Kováčik, Dušan},
booktitle = {2nd Plasma Nanotechnologies and Bioapplications Workshop},
keywords = {ultra-thin glass; flexible electronics; conductive layer; DCSBD plasma; industrial corona; cleaning; activation},
language = {eng},
isbn = {978-80-210-9946-3},
title = {Atmospheric-pressure plasma treatment of ultra-thin flexible glass for deposition of conductive layers},
url = {https://munispace.muni.cz/library/catalog/book/2111},
year = {2021}
}
TY - CONF
ID - 1801303
AU - Sihelník, Slavomír - Krumpolec, Richard - Homola, Tomáš - Feng, Jianyu - Kosová, Eva - Jamaati Kenari, Ali - Stupavská, Monika - Kelar, Jakub - Černák, Mirko - Kováčik, Dušan
PY - 2021
TI - Atmospheric-pressure plasma treatment of ultra-thin flexible glass for deposition of conductive layers
SN - 9788021099463
KW - ultra-thin glass
KW - flexible electronics
KW - conductive layer
KW - DCSBD plasma
KW - industrial corona
KW - cleaning
KW - activation
UR - https://munispace.muni.cz/library/catalog/book/2111
N2 - Flexible electronics are nowadays manufactured on substrates that include polymer foils, paper or flexible glass. The various properties of the available materials predestine flexible electronics for applications ranging from biomedicine throughout the electronic industry to energy harvesting. Ultra-thin flexible glass (UTFG) is a novel material with chemical, electrical and optical properties that are attractive for applications in the manufacturing of optoelectronic devices like sensors, filters, displays and photovoltaic cells. UTFG is produced using the down-draw method, which results in different surface properties compared to common float glass. UTFG has relatively low surface free energy, which leads to weak wetting properties of its surface that could hinder coating depositions of liquid precursors. Most studies aimed at flexible conductive layers on glass surfaces were carried out on standard microscopic glass slides. The present research targets practical application of flexible conductive layers on glass and is focused on organic polymer coating deposition on UTFG with respect to implementation into roll-to-roll ink-jet printing systems for large scale electronics production [1].
ER -
SIHELNÍK, Slavomír, Richard KRUMPOLEC, Tomáš HOMOLA, Jianyu FENG, Eva KOSOVÁ, Ali JAMAATI KENARI, Monika STUPAVSKÁ, Jakub KELAR, Mirko ČERNÁK a Dušan KOVÁČIK. Atmospheric-pressure plasma treatment of ultra-thin flexible glass for deposition of conductive layers. In \textit{2nd Plasma Nanotechnologies and Bioapplications Workshop}. 2021. ISBN~978-80-210-9946-3.
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