Improving the electromechanical performance of dielectric elastomers using silicone rubber and dopamine coated barium titanate

Liang Jiang; Anthony Betts; David Kennedy; Stephen Jerrams

doi:10.1016/j.matdes.2015.07.075

Improving the electromechanical performance of dielectric elastomers using silicone rubber and dopamine coated barium titanate

Liang Jiang, Anthony Betts, David Kennedy, Stephen Jerrams

Faculty of Sciences and Health

Research output: Contribution to journal › Article › peer-review

Abstract

In this work, a new soft dielectric elastomer (DE) was fabricated from dopamine coated barium titanate particles and silicone rubber (SR). The results showed that the barium titanate (BaTiO₃, BT) was coated by dopamine and the coated particles were highly compatible with SR. In order to achieve a maximum voltage-induced deformation, the minimum secant moduli of DEs were obtained in experimentation at a stretch ratio of approximately 1.6 by applying equi-biaxial tensile strain using the bubble inflation method. Additionally, it was found that the addition of DP-BT into SR led to an increased dielectric constant and decreased dielectric loss tangent for the matrix by comparison with SR/BT composites. Furthermore, the electromechanical properties of the SR/DP-BT composites were greatly improved in terms of voltage-induced deformation (s_a), electromechanical energy density (e) and coupling efficiency (K²). A maximum actuated area strain of approximately 78%, which was 30% larger than that of the SR/BT composites, was achieved for the sample having a DP-BT content of 20wt.%. This strain corresponded to a low dielectric strength of around 53V/μm, the composite exhibited a maximum energy density of 0.07MJ/m³ and coupling efficiency of 0.68.

Original language	English
Pages (from-to)	733-742
Number of pages	10
Journal	Materials and Design
Volume	85
DOIs	https://doi.org/10.1016/j.matdes.2015.07.075
Publication status	Published - 15 Nov 2015

Keywords

Dielectric elastomers
Electromechanical coupling efficiency
Energy density
Equi-biaxial stretch
Voltage-induced deformation

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10.1016/j.matdes.2015.07.075

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title = "Improving the electromechanical performance of dielectric elastomers using silicone rubber and dopamine coated barium titanate",

abstract = "In this work, a new soft dielectric elastomer (DE) was fabricated from dopamine coated barium titanate particles and silicone rubber (SR). The results showed that the barium titanate (BaTiO3, BT) was coated by dopamine and the coated particles were highly compatible with SR. In order to achieve a maximum voltage-induced deformation, the minimum secant moduli of DEs were obtained in experimentation at a stretch ratio of approximately 1.6 by applying equi-biaxial tensile strain using the bubble inflation method. Additionally, it was found that the addition of DP-BT into SR led to an increased dielectric constant and decreased dielectric loss tangent for the matrix by comparison with SR/BT composites. Furthermore, the electromechanical properties of the SR/DP-BT composites were greatly improved in terms of voltage-induced deformation (sa), electromechanical energy density (e) and coupling efficiency (K2). A maximum actuated area strain of approximately 78%, which was 30% larger than that of the SR/BT composites, was achieved for the sample having a DP-BT content of 20wt.%. This strain corresponded to a low dielectric strength of around 53V/μm, the composite exhibited a maximum energy density of 0.07MJ/m3 and coupling efficiency of 0.68.",

keywords = "Dielectric elastomers, Electromechanical coupling efficiency, Energy density, Equi-biaxial stretch, Voltage-induced deformation",

author = "Liang Jiang and Anthony Betts and David Kennedy and Stephen Jerrams",

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AU - Jiang, Liang

AU - Betts, Anthony

AU - Kennedy, David

AU - Jerrams, Stephen

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Y1 - 2015/11/15

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AB - In this work, a new soft dielectric elastomer (DE) was fabricated from dopamine coated barium titanate particles and silicone rubber (SR). The results showed that the barium titanate (BaTiO3, BT) was coated by dopamine and the coated particles were highly compatible with SR. In order to achieve a maximum voltage-induced deformation, the minimum secant moduli of DEs were obtained in experimentation at a stretch ratio of approximately 1.6 by applying equi-biaxial tensile strain using the bubble inflation method. Additionally, it was found that the addition of DP-BT into SR led to an increased dielectric constant and decreased dielectric loss tangent for the matrix by comparison with SR/BT composites. Furthermore, the electromechanical properties of the SR/DP-BT composites were greatly improved in terms of voltage-induced deformation (sa), electromechanical energy density (e) and coupling efficiency (K2). A maximum actuated area strain of approximately 78%, which was 30% larger than that of the SR/BT composites, was achieved for the sample having a DP-BT content of 20wt.%. This strain corresponded to a low dielectric strength of around 53V/μm, the composite exhibited a maximum energy density of 0.07MJ/m3 and coupling efficiency of 0.68.

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KW - Energy density

KW - Equi-biaxial stretch

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Improving the electromechanical performance of dielectric elastomers using silicone rubber and dopamine coated barium titanate

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Keywords

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