Enhanced tunable dielectric properties of Ba0.6Sr0.4TiO3/PVDF composites through dual-gradient structural engineering

Materials with tunable dielectric properties were expected to be applied in electronic devices such as phased array antennas, tunable filters and phase shifters. The dielectric tunability of material greatly depends on the dielectric constant and breakdown strength. Herein, two kinds of Ba0.6Sr0.4Ti...

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Veröffentlicht in:	Journal of alloys and compounds 2022-11, Vol.920, p.166034, Article 166034
Hauptverfasser:	Guo, Yiting, Liu, Shuhang, Wu, Sichen, Xu, Jie, Pawlikowska, Emilia, Bulejak, Weronika, Szafran, Mikołaj, Rydosz, Artur, Gao, Feng
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Sprache:	eng
Schlagworte:	Antenna arrays Composite materials Computer simulation Dielectric breakdown Dielectric properties Dielectric strength Electronic devices Finite element method Mathematical models Multilayers Permittivity Phase shifters Phased arrays Polymer matrix composites Structural engineering Tunable filters
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container_title	Journal of alloys and compounds
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creator	Guo, Yiting Liu, Shuhang Wu, Sichen Xu, Jie Pawlikowska, Emilia Bulejak, Weronika Szafran, Mikołaj Rydosz, Artur Gao, Feng
description	Materials with tunable dielectric properties were expected to be applied in electronic devices such as phased array antennas, tunable filters and phase shifters. The dielectric tunability of material greatly depends on the dielectric constant and breakdown strength. Herein, two kinds of Ba0.6Sr0.4TiO3/PVDF (BST/PVDF) composite materials with different dual-gradient structures were designed to obtain the serialized relative permittivity and improved breakdown strength. The numerical simulation based on Yamada theory confirmed that the multilayer dual-gradient structure design was beneficial to improve the dielectric constant, and the enhancement of breakdown strength was further identified by finite element simulation. The optimal composition has a high dielectric tunability of 78.27 % which is 45 % higher than the ungraded composite due to the high permittivity of 33.8 and high breakdown strength of 1900 kV/cm. The dielectric theoretical model of multilayer structure was developed by introducing the effect factor of layer number m into the Yamada model, and the calculated results are consistent with the experimental results especially m= 1.6–1.7. This work provides a new strategy to effectively improve the dielectric tunability of ceramic/polymer composite materials.
doi_str_mv	10.1016/j.jallcom.2022.166034
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The dielectric tunability of material greatly depends on the dielectric constant and breakdown strength. Herein, two kinds of Ba0.6Sr0.4TiO3/PVDF (BST/PVDF) composite materials with different dual-gradient structures were designed to obtain the serialized relative permittivity and improved breakdown strength. The numerical simulation based on Yamada theory confirmed that the multilayer dual-gradient structure design was beneficial to improve the dielectric constant, and the enhancement of breakdown strength was further identified by finite element simulation. The optimal composition has a high dielectric tunability of 78.27 % which is 45 % higher than the ungraded composite due to the high permittivity of 33.8 and high breakdown strength of 1900 kV/cm. The dielectric theoretical model of multilayer structure was developed by introducing the effect factor of layer number m into the Yamada model, and the calculated results are consistent with the experimental results especially m= 1.6–1.7. 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The dielectric theoretical model of multilayer structure was developed by introducing the effect factor of layer number m into the Yamada model, and the calculated results are consistent with the experimental results especially m= 1.6–1.7. 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The dielectric tunability of material greatly depends on the dielectric constant and breakdown strength. Herein, two kinds of Ba0.6Sr0.4TiO3/PVDF (BST/PVDF) composite materials with different dual-gradient structures were designed to obtain the serialized relative permittivity and improved breakdown strength. The numerical simulation based on Yamada theory confirmed that the multilayer dual-gradient structure design was beneficial to improve the dielectric constant, and the enhancement of breakdown strength was further identified by finite element simulation. The optimal composition has a high dielectric tunability of 78.27 % which is 45 % higher than the ungraded composite due to the high permittivity of 33.8 and high breakdown strength of 1900 kV/cm. The dielectric theoretical model of multilayer structure was developed by introducing the effect factor of layer number m into the Yamada model, and the calculated results are consistent with the experimental results especially m= 1.6–1.7. This work provides a new strategy to effectively improve the dielectric tunability of ceramic/polymer composite materials.</abstract><cop>Lausanne</cop><pub>Elsevier BV</pub><doi>10.1016/j.jallcom.2022.166034</doi></addata></record>
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subjects	Antenna arrays Composite materials Computer simulation Dielectric breakdown Dielectric properties Dielectric strength Electronic devices Finite element method Mathematical models Multilayers Permittivity Phase shifters Phased arrays Polymer matrix composites Structural engineering Tunable filters
title	Enhanced tunable dielectric properties of Ba0.6Sr0.4TiO3/PVDF composites through dual-gradient structural engineering
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