Mechanical properties of hybrid graphene nanoplatelet-nanosilica filled unidirectional basalt fibre composites
Basalt fibre (BF) is one of the most promising reinforcing natural materials for polymer composites that could replace the usage of glass fibre due to its comparable properties. The aim of adding nanofiller in polymer composites is to enhance the mechanical properties of the composites. In theory, t...
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MDPI AG
2021
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2-s2.0-85106957536 Hashim U.R.; Jumahat A.; Jawaid M. Mechanical properties of hybrid graphene nanoplatelet-nanosilica filled unidirectional basalt fibre composites 2021 Nanomaterials 11 6 10.3390/nano11061468 https://www.scopus.com/inward/record.uri?eid=2-s2.0-85106957536&doi=10.3390%2fnano11061468&partnerID=40&md5=e6c8f0759f734db25621986083d5804d Basalt fibre (BF) is one of the most promising reinforcing natural materials for polymer composites that could replace the usage of glass fibre due to its comparable properties. The aim of adding nanofiller in polymer composites is to enhance the mechanical properties of the composites. In theory, the incorporation of high strength and stiffness nanofiller, namely graphene nanoplatelet (GNP), could create superior composite properties. However, the main challenges of incorporating this nanofiller are its poor dispersion state and aggregation in epoxy due to its high surface area and strong Van der Waals forces in between graphene sheets. In this study, we used one of the effective methods of functionalization to improve graphene’s dispersion and also introducing nanosilica filler to enhance platelets shear mechanism. The high dispersive silica nanospheres were introduced in the tactoids morphology of stacked graphene nanosheets in order to produce high shear forces during milling and exfoliate the GNP. The hybrid nanofiller modified epoxy polymers were impregnated into BF to evaluate the mechanical properties of the basalt fibre reinforced polymeric (BFRP) system under tensile, compression, flexural, and drop-weight impact tests. In response to the synergistic effect of zero-dimensional nanosilica and two-dimensional graphene nanoplatelets enhanced the mechanical properties of BFRP, especially in Basalt fibre + 0.2 wt% GNP/15 wt% NS (BF-H0.2) with the highest increment in modulus and strength to compare with unmodified BF. These findings also revealed that the incorporation of hybrid nanofiller contributed to the improvement in the mechanical properties of the composite. BF has huge potential as an alternative to the synthetic glass fibre for the fabrication of mechanical components and structures. © 2021 by the authors. Licensee MDPI, Basel, Switzerland. MDPI AG 20794991 English Article All Open Access; Gold Open Access; Green Open Access |
author |
Hashim U.R.; Jumahat A.; Jawaid M. |
spellingShingle |
Hashim U.R.; Jumahat A.; Jawaid M. Mechanical properties of hybrid graphene nanoplatelet-nanosilica filled unidirectional basalt fibre composites |
author_facet |
Hashim U.R.; Jumahat A.; Jawaid M. |
author_sort |
Hashim U.R.; Jumahat A.; Jawaid M. |
title |
Mechanical properties of hybrid graphene nanoplatelet-nanosilica filled unidirectional basalt fibre composites |
title_short |
Mechanical properties of hybrid graphene nanoplatelet-nanosilica filled unidirectional basalt fibre composites |
title_full |
Mechanical properties of hybrid graphene nanoplatelet-nanosilica filled unidirectional basalt fibre composites |
title_fullStr |
Mechanical properties of hybrid graphene nanoplatelet-nanosilica filled unidirectional basalt fibre composites |
title_full_unstemmed |
Mechanical properties of hybrid graphene nanoplatelet-nanosilica filled unidirectional basalt fibre composites |
title_sort |
Mechanical properties of hybrid graphene nanoplatelet-nanosilica filled unidirectional basalt fibre composites |
publishDate |
2021 |
container_title |
Nanomaterials |
container_volume |
11 |
container_issue |
6 |
doi_str_mv |
10.3390/nano11061468 |
url |
https://www.scopus.com/inward/record.uri?eid=2-s2.0-85106957536&doi=10.3390%2fnano11061468&partnerID=40&md5=e6c8f0759f734db25621986083d5804d |
description |
Basalt fibre (BF) is one of the most promising reinforcing natural materials for polymer composites that could replace the usage of glass fibre due to its comparable properties. The aim of adding nanofiller in polymer composites is to enhance the mechanical properties of the composites. In theory, the incorporation of high strength and stiffness nanofiller, namely graphene nanoplatelet (GNP), could create superior composite properties. However, the main challenges of incorporating this nanofiller are its poor dispersion state and aggregation in epoxy due to its high surface area and strong Van der Waals forces in between graphene sheets. In this study, we used one of the effective methods of functionalization to improve graphene’s dispersion and also introducing nanosilica filler to enhance platelets shear mechanism. The high dispersive silica nanospheres were introduced in the tactoids morphology of stacked graphene nanosheets in order to produce high shear forces during milling and exfoliate the GNP. The hybrid nanofiller modified epoxy polymers were impregnated into BF to evaluate the mechanical properties of the basalt fibre reinforced polymeric (BFRP) system under tensile, compression, flexural, and drop-weight impact tests. In response to the synergistic effect of zero-dimensional nanosilica and two-dimensional graphene nanoplatelets enhanced the mechanical properties of BFRP, especially in Basalt fibre + 0.2 wt% GNP/15 wt% NS (BF-H0.2) with the highest increment in modulus and strength to compare with unmodified BF. These findings also revealed that the incorporation of hybrid nanofiller contributed to the improvement in the mechanical properties of the composite. BF has huge potential as an alternative to the synthetic glass fibre for the fabrication of mechanical components and structures. © 2021 by the authors. Licensee MDPI, Basel, Switzerland. |
publisher |
MDPI AG |
issn |
20794991 |
language |
English |
format |
Article |
accesstype |
All Open Access; Gold Open Access; Green Open Access |
record_format |
scopus |
collection |
Scopus |
_version_ |
1809677596955246592 |