A molecular perspective to analytical modeling that reveals new instabilities in dielectric elastomer transducers

A molecular perspective to analytical modeling that reveals new instabilities in dielectric elastomer transducers

•Edward–Vilgis model provides excellent fit for dielectric elastomers.•Uncoiling of chain entanglements may lead to electromechanical instability.•Mechanical instability is predicted for highly entangled elastomers.•Guidelines for averting electromechanical instability.•Guidelines for tailor made di...

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Veröffentlicht in:Journal of the mechanics and physics of solids 2019-11, Vol.132, p.103703, Article 103703
Hauptverfasser: Mathew, Anup Teejo, Vo, Tran Vy Khanh, Koh, Soo Jin Adrian
Format: Artikel
Sprache:eng
Schlagworte:
Crosslinking
Crosslinks
Dielectric elastomer
Dielectric properties
Elastomers
Entanglements
Instabilities
Material model
Material properties
Nonlinear response
Plastic deformation
Slip resistance
Slippage
Softening
Stability analysis
Transducers
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creator Mathew, Anup Teejo
Vo, Tran Vy Khanh
Koh, Soo Jin Adrian
description •Edward–Vilgis model provides excellent fit for dielectric elastomers.•Uncoiling of chain entanglements may lead to electromechanical instability.•Mechanical instability is predicted for highly entangled elastomers.•Guidelines for averting electromechanical instability.•Guidelines for tailor made dielectric elastomers. We use a four-parameter material model for polymers - the Edward–Vilgis (EV) model, which models polymeric crosslinks, sliplinks, slippage and inextensibility to analyze dielectric elastomers (DEs). The EV model allows us to investigate the DE response from a molecular perspective, revealing new instabilities in DEs, primarily due to sliplinks. We compare the EV model with the Gent model – a crosslink-only model commonly used in the field of DE, on its ability to fit the non-linear stress–strain response of an acrylic elastomer (VHB 4905), which contains a significant amount of entanglements. We found that the EV model provided an excellent fit to the strain softening phenomenon at small to modest strains, which is missed by the Gent model. Slippage of sliplinks at these regions of strain produces slip resistance that contributed to enhance the resistance to applied forces. Subsequent slip relaxation due to the uncoiling of entanglements will lead to significant strain softening, giving the DE a higher susceptibility to mechanically and electro-mechanically-induced instabilities. From our analyses, we produced mechanical stability phase plots and electromechanical stability design plots, for elastomers of different sliplink-to-crosslink compositions. Such plots may serve as guides to develop dielectric elastomers with desired material properties and performances, and tailor to specific applications.
doi_str_mv 10.1016/j.jmps.2019.103703
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We use a four-parameter material model for polymers - the Edward–Vilgis (EV) model, which models polymeric crosslinks, sliplinks, slippage and inextensibility to analyze dielectric elastomers (DEs). The EV model allows us to investigate the DE response from a molecular perspective, revealing new instabilities in DEs, primarily due to sliplinks. We compare the EV model with the Gent model – a crosslink-only model commonly used in the field of DE, on its ability to fit the non-linear stress–strain response of an acrylic elastomer (VHB 4905), which contains a significant amount of entanglements. We found that the EV model provided an excellent fit to the strain softening phenomenon at small to modest strains, which is missed by the Gent model. Slippage of sliplinks at these regions of strain produces slip resistance that contributed to enhance the resistance to applied forces. Subsequent slip relaxation due to the uncoiling of entanglements will lead to significant strain softening, giving the DE a higher susceptibility to mechanically and electro-mechanically-induced instabilities. From our analyses, we produced mechanical stability phase plots and electromechanical stability design plots, for elastomers of different sliplink-to-crosslink compositions. 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We use a four-parameter material model for polymers - the Edward–Vilgis (EV) model, which models polymeric crosslinks, sliplinks, slippage and inextensibility to analyze dielectric elastomers (DEs). The EV model allows us to investigate the DE response from a molecular perspective, revealing new instabilities in DEs, primarily due to sliplinks. We compare the EV model with the Gent model – a crosslink-only model commonly used in the field of DE, on its ability to fit the non-linear stress–strain response of an acrylic elastomer (VHB 4905), which contains a significant amount of entanglements. We found that the EV model provided an excellent fit to the strain softening phenomenon at small to modest strains, which is missed by the Gent model. Slippage of sliplinks at these regions of strain produces slip resistance that contributed to enhance the resistance to applied forces. Subsequent slip relaxation due to the uncoiling of entanglements will lead to significant strain softening, giving the DE a higher susceptibility to mechanically and electro-mechanically-induced instabilities. From our analyses, we produced mechanical stability phase plots and electromechanical stability design plots, for elastomers of different sliplink-to-crosslink compositions. 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Subsequent slip relaxation due to the uncoiling of entanglements will lead to significant strain softening, giving the DE a higher susceptibility to mechanically and electro-mechanically-induced instabilities. From our analyses, we produced mechanical stability phase plots and electromechanical stability design plots, for elastomers of different sliplink-to-crosslink compositions. Such plots may serve as guides to develop dielectric elastomers with desired material properties and performances, and tailor to specific applications.</abstract><cop>London</cop><pub>Elsevier Ltd</pub><doi>10.1016/j.jmps.2019.103703</doi></addata></record>
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source ScienceDirect Journals (5 years ago - present)
subjects Crosslinking
Crosslinks
Dielectric elastomer
Dielectric properties
Elastomers
Entanglements
Instabilities
Material model
Material properties
Nonlinear response
Plastic deformation
Slip resistance
Slippage
Softening
Stability analysis
Transducers
title A molecular perspective to analytical modeling that reveals new instabilities in dielectric elastomer transducers
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