Login
Register
Reset Password
Publish & Distribute
Publishing Solutions
Distribution Solutions
Subjects
Architecture and Design
Arts
Business and Economics
Chemistry
Classical and Ancient Near Eastern Studies
Computer Sciences
Cultural Studies
Engineering
General Interest
Geosciences
History
Industrial Chemistry
Jewish Studies
Law
Library and Information Science, Book Studies
Life Sciences
Linguistics and Semiotics
Literary Studies
Materials Sciences
Mathematics
Medicine
Music
Pharmacy
Philosophy
Physics
Social Sciences
Sports and Recreation
Theology and Religion
Publications
Journals
Books
Proceedings
Publishers
Blog
Contact
Search
EUR
USD
GBP
English
English
Deutsch
Polski
Español
Français
Italiano
Cart
Home
Journals
Fatigue of Aircraft Structures
Volume 2022 (2022): Issue 14 (December 2022)
Open Access
Impact of Carbon Nanotubes on the Mechanical and Electrical Properties of Silicone
Michał Sałaciński
Michał Sałaciński
,
Kamil Dydek
Kamil Dydek
,
Andrzej Leski
Andrzej Leski
,
Rafał Kozera
Rafał Kozera
,
Mateusz Mucha
Mateusz Mucha
and
Wojciech Karczmarz
Wojciech Karczmarz
| Nov 28, 2023
Fatigue of Aircraft Structures
Volume 2022 (2022): Issue 14 (December 2022)
About this article
Previous Article
Next Article
Abstract
Article
Figures & Tables
References
Authors
Articles in this Issue
Preview
PDF
Cite
Share
Article Category:
research article
Published Online:
Nov 28, 2023
Page range:
135 - 153
DOI:
https://doi.org/10.2478/fas-2022-0010
Keywords
nanotubes
,
silicon
,
mechanical properties
,
electrical properties
© 2022 Michał Sałaciński et al., published by Sciendo
This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.
Figure 1.
Mechanical and electrical test specimen: (a) Schematic of the specimen; (b) Sample on the test bench.
Figure 2.
Schematic diagram of an electrical test bench.
Figure 3.
Rheological properties of silicone/MWCNTs nanocomposites: (a) Complex viscosity as a function of frequency; (b) Storage modulus as a function of frequency; (c) Loss modulus as a function of frequency. MWCNTs, multi-walled carbon nanotubes.
Figure 4.
Optical micrographs of produced materials: (a) neat silicone, (b) silicone with 4 wt.% of MWCNTs, (c) silicone with 6 wt.% of MWCNTs, (d) silicone with 8 wt.% of MWCNTs. MWCNTs, multi-walled carbon nanotubes.
Figure 5.
Effect of nanotube content on Shor hardness factor A, s – standard deviation.
Figure 6.
Effect of nanotube content on the stiffness of silicone, (a) stresses as a function of strain – mean values from three measurements for one material; (b) elastic moduli. s – standard deviation.
Figure 7.
Effect of nanotube content on: (a) Poisson’s ratio of the silicone; (b) compressibility. s – standard deviation.
Figure 8.
Current density as a function of voltage for silicone-filled with 4% nanotubes.
Figure 9.
Current density as a function of voltage for silicone-filled with 6% nanotubes.
Figure 10.
Current density as a function of voltage for silicone-filled with 8% nanotubes.