Effect of ionic liquid on soft epoxy-amine electroactuators

Energy conversion represents a challenge in various fields of applications such as soft robotics or microfluidics technologies, particularly in terms of electromechanical coupling for actuators. The dielectric elastomers are a variety of electroactive polymers (EAP) which require high electric field...

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Bibliographic Details
Published in:Polymer (Guilford) 2024-10, Vol.312, p.127601, Article 127601
Main Authors: Blain, Axel, Perrin, Véronique, Seveyrat, Laurence, Dalmas, Florent, Livi, Sébastien, Courbon, Joël, Diguet, Gildas, Takana, Hidemasa, Cavaillé, Jean-Yves, Coativy, Gildas
Format: Article
Language:English
Subjects:
Bending
Conductivity
Elastomer
Electric field
Engineering Sciences
Ionic liquid
Physics
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Summary:Energy conversion represents a challenge in various fields of applications such as soft robotics or microfluidics technologies, particularly in terms of electromechanical coupling for actuators. The dielectric elastomers are a variety of electroactive polymers (EAP) which require high electric fields to be used as actuators. It is well-known that the presence of ionic impurities can have an influence of their electro-mechanical response under high electric field (i.e. above 1 MV/m). More precisely, it can be responsible for the bending of the sample under constant electric field. Here, we investigate the impact of a small content, i.e. from 0.1 wt% to 10 wt% of an imidazolium Ionic Liquid (IL) on the electromechanical response of a soft epoxy-amine network. The interest of this study therefore lies in its position at the frontier between dielectric polymers and ionic polymers. Dielectric spectroscopy revealed a significant increase of electric conductivity (≈2 orders of magnitude) when adding only 0.1 wt% of IL and up to 4 orders of magnitude with 10 wt% of IL at T = 20 °C for f = 10 Hz. It also evidenced the presence of the electrode polarization for all the samples doped with IL. The bending test carried out at E = 0.1 MV/m revealed no bending for pure epoxy-amine and a slow kinetics of bending for all the samples doped with IL with displacement evolving throughout the experiment (i.e. over 4 h). As evidenced by dielectric spectroscopy and bending tests, it is clear that the presence of a small quantity of ionic moieties (whether doping agent or impurity) can strongly modify the electromechanical behavior of elastomer commonly described as dielectric. [Display omitted] •Study of epoxy-amine doped with 0.1–10%wt of BMIM-TFSI (an ionic liquid).•Conductivity increases by 4 orders of magnitude with 10%wt of IL.•Electrode polarization is detected in the presence of IL.•0.1%wt of IL is sufficient to cause bending under an electric field.
ISSN:0032-3861
DOI:10.1016/j.polymer.2024.127601