Ultra high permittivity and significantly enhanced electric field induced strain in PEDOT:PSS-RGO@PU intelligent shape-changing electro-active polymers
Large deformation of soft materials is harnessed to provide functions in the nascent field of soft machines. In this work, PEDOT:PSS noncovalent functionalized graphene-polyurethane dielectric elastomer composites (PEDOT:PSS-RGO@PU) have been synthesized as promising candidate materials for micro-ac...
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Published in | RSC advances Vol. 4; no. 19; pp. 6461 - 6467 |
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Main Authors | , , , , , , |
Format | Journal Article |
Language | English |
Published |
01.01.2014
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Online Access | Get full text |
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Summary: | Large deformation of soft materials is harnessed to provide functions in the nascent field of soft machines. In this work, PEDOT:PSS noncovalent functionalized graphene-polyurethane dielectric elastomer composites (PEDOT:PSS-RGO@PU) have been synthesized as promising candidate materials for micro-actuator electromechanical applications. PEDOT:PSS conducting polymer chains not only reinforce the interaction between the polyurethane matrix and graphene sheets, but also prevent graphene sheets from aggregating and connecting, which are beneficial to forming microcapacitors in the matrix and suppressing the leakage current. The PEDOT:PSS-RGO@PU composite exhibits ultra high permittivity (350 at 1 kHz), low dielectric loss (∼0.2 at 1 kHz), low loss modulus (200 MPa), and low loss tangent (∼0.4), all being essential to create a high performance electric-induced strain material. The maximum thickness strain of 164% is significantly higher than reported values for polyurethane elastomers and nanocomposites.
A novel PEDOT:PSS-RGO@PU flexible micro-actuator with an extra high electric field induced strain of 164%. |
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ISSN: | 2046-2069 2046-2069 |
DOI: | 10.1039/c4ra10695d |