On the effect of nanoparticle surface chemistry on the electrical characteristics of epoxy-based nanocomposites
On the effect of nanoparticle surface chemistry on the electrical characteristics of epoxy-based nanocomposites
The effect of nanosilica surface chemistry on the electrical behavior of epoxy-based nanocomposites is described. The nanosilica was reacted with different volumes of (3-glycidyloxypropyl)trimethoxysilane and the efficacy of the process was demonstrated by infrared spectroscopy and combustion analysis. Nanocomposites containing 2 wt% of nanosilica were prepared and characterized by scanning electron microscopy (SEM), AC ramp electrical breakdown testing, differential scanning calorimetry (DSC) and dielectric spectroscopy. SEM examination indicated that, although the nanoparticle dispersion improved somewhat as the degree of surface functionalization increased, all samples nevertheless contained agglomerates. Despite the non-ideal nature of the samples, major improvements in breakdown strength (from 182 ± 5 kV mm-1 to 268 ± 12 kV mm-1) were observed in systems formulated from optimally treated nanosilicas. DSC studies of the glass transition revealed no evidence for any modified interphase regions between the nanosilica and the matrix, but interfacial effects were evident in the dielectric spectra. In particular, changes in the magnitude of the real part of the permittivity and variations in the interfacial ?’-relaxation suggest that the observed changes in breakdown performance stem from variations in the polar character of the nanosilica surface, which may affect the local density of trapping states and, thereby, charge transport dynamics.
1-16
Yeung, Celia
6de1d1c9-991e-4501-ac7c-5b45f8d6b1a2
Vaughan, Alun
6d813b66-17f9-4864-9763-25a6d659d8a3
6 April 2016
Yeung, Celia
6de1d1c9-991e-4501-ac7c-5b45f8d6b1a2
Vaughan, Alun
6d813b66-17f9-4864-9763-25a6d659d8a3
Yeung, Celia and Vaughan, Alun
(2016)
On the effect of nanoparticle surface chemistry on the electrical characteristics of epoxy-based nanocomposites.
[in special issue: Nano- and Microcomposites for Electrical Engineering Applications]
Polymers, 8 (4), , [126].
(doi:10.3390/polym8040126).
Abstract
The effect of nanosilica surface chemistry on the electrical behavior of epoxy-based nanocomposites is described. The nanosilica was reacted with different volumes of (3-glycidyloxypropyl)trimethoxysilane and the efficacy of the process was demonstrated by infrared spectroscopy and combustion analysis. Nanocomposites containing 2 wt% of nanosilica were prepared and characterized by scanning electron microscopy (SEM), AC ramp electrical breakdown testing, differential scanning calorimetry (DSC) and dielectric spectroscopy. SEM examination indicated that, although the nanoparticle dispersion improved somewhat as the degree of surface functionalization increased, all samples nevertheless contained agglomerates. Despite the non-ideal nature of the samples, major improvements in breakdown strength (from 182 ± 5 kV mm-1 to 268 ± 12 kV mm-1) were observed in systems formulated from optimally treated nanosilicas. DSC studies of the glass transition revealed no evidence for any modified interphase regions between the nanosilica and the matrix, but interfacial effects were evident in the dielectric spectra. In particular, changes in the magnitude of the real part of the permittivity and variations in the interfacial ?’-relaxation suggest that the observed changes in breakdown performance stem from variations in the polar character of the nanosilica surface, which may affect the local density of trapping states and, thereby, charge transport dynamics.
Text
Polymers CYHE Revised.pdf
- Accepted Manuscript
Text
polymers-08-00126.pdf
- Version of Record
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Accepted/In Press date: 16 March 2016
e-pub ahead of print date: 6 April 2016
Published date: 6 April 2016
Organisations:
EEE
Identifiers
Local EPrints ID: 390836
URI: http://eprints.soton.ac.uk/id/eprint/390836
ISSN: 2073-4360
PURE UUID: 22727662-cc4d-441c-8c76-21af777b314f
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Date deposited: 07 Apr 2016 13:18
Last modified: 15 Mar 2024 03:06
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Author:
Celia Yeung
Author:
Alun Vaughan
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