Detail publikace
Basalt fibre surface modification via plasma polymerization of tetravinylsilane/oxygen mixtures for improved interfacial adhesion with unsaturated polyester matrix
JURKO, M. ČECH, V.
Originální název
Basalt fibre surface modification via plasma polymerization of tetravinylsilane/oxygen mixtures for improved interfacial adhesion with unsaturated polyester matrix
Typ
článek v časopise ve Web of Science, Jimp
Jazyk
angličtina
Originální abstrakt
With the aim of optimizing the interfacial adhesion of basalt fibres with thermoset matrices, in this research the plasma polymerization technique (PECVD) was used to synthesize polymeric coatings based on tetravinylsilane (TVS) or its mixtures with oxygen on the surface of basalt fibres. The successful deposition of the polymer sizing was confirmed by XPS analysis, which highlighted the increase in the intensity of the carbon and oxygen peaks. To evaluate the influence of polymer sizing on interfacial adhesion, basalt fibre / polyester resin composites were tested through the short beam shear (SBS) test. Compared to neat basalt fibres, the modified fibres showed a remarkable increase in ILSS higher than 180%. These results compared quite favourably with those on glass fibres used as baseline, with higher ILSS values as a function of oxygen content. The improvement in interfacial adhesion was correlated with the increase in basalt fibre surface energy and dispersive component by single fibre dynamic contact angle tests.
Klíčová slova
Fibre/matrix interface; Adhesion; Mechanical properties; Basalt fibres; Plasma polymerization
Autoři
JURKO, M.; ČECH, V.
Vydáno
7. 8. 2021
Nakladatel
Elsevier
ISSN
0254-0584
Periodikum
MATERIALS CHEMISTRY AND PHYSICS
Ročník
122
Číslo
7
Stát
Švýcarská konfederace
Strany od
1
Strany do
7
Strany počet
7
URL
BibTex
@article{BUT172556,
author="Michal {Jurko} and Vladimír {Čech}",
title="Basalt fibre surface modification via plasma polymerization of tetravinylsilane/oxygen mixtures for improved interfacial adhesion with unsaturated polyester matrix",
journal="MATERIALS CHEMISTRY AND PHYSICS",
year="2021",
volume="122",
number="7",
pages="1--7",
doi="10.1016/j.matchemphys.2021.125106",
issn="0254-0584",
url="https://www.sciencedirect.com/science/article/pii/S0254058421008890?via%3Dihub"
}