Development, dielectric response, and functionality of ZnTiO3/BaTiO3/epoxy resin hybrid nanocomposites
Development, dielectric response, and functionality of ZnTiO3/BaTiO3/epoxy resin hybrid nanocomposites
In the present work, hybrid nanocomposites of an epoxy resin reinforced with ZnTiO3 and BaTiO3 nanoparticles, at various filler contents, were fabricated and studied. The successful integration of ceramic nanofillers and the fine distribution of nanoparticles were confirmed via X-ray Diffraction patterns and Scanning Electron Microscopy images, respectively. Dielectric properties and related relaxation phenomena were investigated via Broadband Dielectric Spectroscopy in a wide range of frequencies and temperatures. Data analysis showed that dielectric permittivity increases with filler content, although optimum performance does not correspond to the maximum ZnTiO3 content. Four relaxation processes were observed and attributed to interfacial polarization (IP) (at low frequencies and high temperatures), glass-to-rubber transition (α-relaxation) of the epoxy matrix (at intermediate frequencies and temperatures), and local rearrangements of polar side groups of the macromolecules (β-relaxation) and small flexible groups of the main polymer chain (γ-relaxation) occurring at low temperatures and high frequencies. The ability of hybrid nanocomposites to store and retrieve energy was studied under dc conditions by employing a charging/discharging sequence. The stored and retrieved energy increases with filler content and charging voltage. The optimum ability of energy recovering, shown by the epoxy/7 phr ZnTiO3/7 phr BaTiO3 nanocomposite, ranges between 30 and 50 times more than the matrix, depending on the time instant. The employed nanoparticles induce piezoelectric properties in the nanocomposites, as found by the increase in the piezoelectric coefficient with filler content.
dielectric properties, energy storing/retrieving, hybrid polymer nanocomposites, piezoelectric properties, relaxations
Patsidis, Anastasios C.
df48425d-7396-4733-9fd3-8bb0cdfe307c
Koufakis, Eleftherios I.
ddcfad78-3356-4fff-bade-45893dcd7c3e
Mathioudakis, Georgios N.
1a69169f-f94a-4e95-b5a1-e75e1fd2943b
Vryonis, Orestis
4affde05-88f2-436f-b036-dceedf31ea9c
Psarras, Georgios C.
488c3089-e396-4e10-8f12-62c9d0bda2b0
15 June 2024
Patsidis, Anastasios C.
df48425d-7396-4733-9fd3-8bb0cdfe307c
Koufakis, Eleftherios I.
ddcfad78-3356-4fff-bade-45893dcd7c3e
Mathioudakis, Georgios N.
1a69169f-f94a-4e95-b5a1-e75e1fd2943b
Vryonis, Orestis
4affde05-88f2-436f-b036-dceedf31ea9c
Psarras, Georgios C.
488c3089-e396-4e10-8f12-62c9d0bda2b0
Patsidis, Anastasios C., Koufakis, Eleftherios I., Mathioudakis, Georgios N., Vryonis, Orestis and Psarras, Georgios C.
(2024)
Development, dielectric response, and functionality of ZnTiO3/BaTiO3/epoxy resin hybrid nanocomposites.
Journal of Composites Science, 8 (6), [225].
(doi:10.3390/jcs8060225).
Abstract
In the present work, hybrid nanocomposites of an epoxy resin reinforced with ZnTiO3 and BaTiO3 nanoparticles, at various filler contents, were fabricated and studied. The successful integration of ceramic nanofillers and the fine distribution of nanoparticles were confirmed via X-ray Diffraction patterns and Scanning Electron Microscopy images, respectively. Dielectric properties and related relaxation phenomena were investigated via Broadband Dielectric Spectroscopy in a wide range of frequencies and temperatures. Data analysis showed that dielectric permittivity increases with filler content, although optimum performance does not correspond to the maximum ZnTiO3 content. Four relaxation processes were observed and attributed to interfacial polarization (IP) (at low frequencies and high temperatures), glass-to-rubber transition (α-relaxation) of the epoxy matrix (at intermediate frequencies and temperatures), and local rearrangements of polar side groups of the macromolecules (β-relaxation) and small flexible groups of the main polymer chain (γ-relaxation) occurring at low temperatures and high frequencies. The ability of hybrid nanocomposites to store and retrieve energy was studied under dc conditions by employing a charging/discharging sequence. The stored and retrieved energy increases with filler content and charging voltage. The optimum ability of energy recovering, shown by the epoxy/7 phr ZnTiO3/7 phr BaTiO3 nanocomposite, ranges between 30 and 50 times more than the matrix, depending on the time instant. The employed nanoparticles induce piezoelectric properties in the nanocomposites, as found by the increase in the piezoelectric coefficient with filler content.
Text
jcs-08-00225
- Version of Record
More information
Accepted/In Press date: 12 June 2024
Published date: 15 June 2024
Keywords:
dielectric properties, energy storing/retrieving, hybrid polymer nanocomposites, piezoelectric properties, relaxations
Identifiers
Local EPrints ID: 493359
URI: http://eprints.soton.ac.uk/id/eprint/493359
ISSN: 2504-477X
PURE UUID: 62f85f63-778e-41ed-ab92-242d417f0ed6
Catalogue record
Date deposited: 30 Aug 2024 16:36
Last modified: 31 Aug 2024 01:49
Export record
Altmetrics
Contributors
Author:
Anastasios C. Patsidis
Author:
Eleftherios I. Koufakis
Author:
Georgios N. Mathioudakis
Author:
Orestis Vryonis
Author:
Georgios C. Psarras
Download statistics
Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.
View more statistics