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Chemical and Physical Properties of the BLT4 Ultra Capacitor—A Suitable Material for Ultracapacitors

This paper describes the properties of a lead-free ceramic material based on barium titanate, designed for the construction of ultracapacitors and sensors used in mechatronic systems. The admixture of lanthanum (La(3+)) served as a modifier. The ceramic powders were obtained by the solid phase react...

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Autores principales: Wodecka-Duś, B., Adamczyk-Habrajska, M., Goryczka, T., Bochenek, D.
Formato: Online Artículo Texto
Lenguaje:English
Publicado: MDPI 2020
Materias:
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC7040727/
https://www.ncbi.nlm.nih.gov/pubmed/32024224
http://dx.doi.org/10.3390/ma13030659
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author Wodecka-Duś, B.
Adamczyk-Habrajska, M.
Goryczka, T.
Bochenek, D.
author_facet Wodecka-Duś, B.
Adamczyk-Habrajska, M.
Goryczka, T.
Bochenek, D.
author_sort Wodecka-Duś, B.
collection PubMed
description This paper describes the properties of a lead-free ceramic material based on barium titanate, designed for the construction of ultracapacitors and sensors used in mechatronic systems. The admixture of lanthanum (La(3+)) served as a modifier. The ceramic powders were obtained by the solid phase reaction method (conventional method—mixed oxides method—MOM). Technological conditions of the synthesis process were determined on the basis of thermal analysis. The obtained samples are characterized, at room temperature (T(r) < T(C)), by a single-phase tetragonal structure and a P4mm space group. Properly developed large grains (d = 5 µm) contributed to the increase in electric permittivity, the maximum value of which is at the level of ε(m) ≈ 112,000, as well as to a strong decrease in specific resistance in the ferroelectric phase, whereas above the Curie temperature, by creating a potential barrier at their boundaries, there was a a rapid increase in resistivity. The temperature coefficient of resistance of the obtained posistor is 10.53%/K. The electrical properties of the obtained ceramics were examined using impedance spectroscopy. In order to analyze the obtained results, a method of comparing the behavior of the real object and its replacement system in a specific frequency region was used, whereas the Kramer–-Kroning (K–K) test was used to determine the consistency of the measured data. The proper selection of the stoichiometry and synthesis conditions resulted in the creation of an appropriate concentration of donor levels and oxygen gaps, which in turn resulted in a significant increase in the value of electrical permittivity, with small values of the angle of dielectric loss tangent. This fact predisposes the discussed material for certain applications (in the construction of ultracapacitors, among others).
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spelling pubmed-70407272020-03-09 Chemical and Physical Properties of the BLT4 Ultra Capacitor—A Suitable Material for Ultracapacitors Wodecka-Duś, B. Adamczyk-Habrajska, M. Goryczka, T. Bochenek, D. Materials (Basel) Article This paper describes the properties of a lead-free ceramic material based on barium titanate, designed for the construction of ultracapacitors and sensors used in mechatronic systems. The admixture of lanthanum (La(3+)) served as a modifier. The ceramic powders were obtained by the solid phase reaction method (conventional method—mixed oxides method—MOM). Technological conditions of the synthesis process were determined on the basis of thermal analysis. The obtained samples are characterized, at room temperature (T(r) < T(C)), by a single-phase tetragonal structure and a P4mm space group. Properly developed large grains (d = 5 µm) contributed to the increase in electric permittivity, the maximum value of which is at the level of ε(m) ≈ 112,000, as well as to a strong decrease in specific resistance in the ferroelectric phase, whereas above the Curie temperature, by creating a potential barrier at their boundaries, there was a a rapid increase in resistivity. The temperature coefficient of resistance of the obtained posistor is 10.53%/K. The electrical properties of the obtained ceramics were examined using impedance spectroscopy. In order to analyze the obtained results, a method of comparing the behavior of the real object and its replacement system in a specific frequency region was used, whereas the Kramer–-Kroning (K–K) test was used to determine the consistency of the measured data. The proper selection of the stoichiometry and synthesis conditions resulted in the creation of an appropriate concentration of donor levels and oxygen gaps, which in turn resulted in a significant increase in the value of electrical permittivity, with small values of the angle of dielectric loss tangent. This fact predisposes the discussed material for certain applications (in the construction of ultracapacitors, among others). MDPI 2020-02-02 /pmc/articles/PMC7040727/ /pubmed/32024224 http://dx.doi.org/10.3390/ma13030659 Text en © 2020 by the authors. Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (http://creativecommons.org/licenses/by/4.0/).
spellingShingle Article
Wodecka-Duś, B.
Adamczyk-Habrajska, M.
Goryczka, T.
Bochenek, D.
Chemical and Physical Properties of the BLT4 Ultra Capacitor—A Suitable Material for Ultracapacitors
title Chemical and Physical Properties of the BLT4 Ultra Capacitor—A Suitable Material for Ultracapacitors
title_full Chemical and Physical Properties of the BLT4 Ultra Capacitor—A Suitable Material for Ultracapacitors
title_fullStr Chemical and Physical Properties of the BLT4 Ultra Capacitor—A Suitable Material for Ultracapacitors
title_full_unstemmed Chemical and Physical Properties of the BLT4 Ultra Capacitor—A Suitable Material for Ultracapacitors
title_short Chemical and Physical Properties of the BLT4 Ultra Capacitor—A Suitable Material for Ultracapacitors
title_sort chemical and physical properties of the blt4 ultra capacitor—a suitable material for ultracapacitors
topic Article
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC7040727/
https://www.ncbi.nlm.nih.gov/pubmed/32024224
http://dx.doi.org/10.3390/ma13030659
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