Graphene/gelatin hydrogel composites with high storage modulus sensitivity for using as electroactive actuator: Effects of surface area and electric field strength
© 2015 Elsevier Ltd. All rights reserved. The electromechanical properties of graphene/gelatin hydrogel composites were investigated under the effects of graphene surface area, electric field strength and temperature towards bio-actuator applications. The highest surface area of an embedded graphene...
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th-cmuir.6653943832-443072018-04-25T07:48:03Z Graphene/gelatin hydrogel composites with high storage modulus sensitivity for using as electroactive actuator: Effects of surface area and electric field strength Thawatchai Tungkavet Nispa Seetapan Datchanee Pattavarakorn Anuvat Sirivat Agricultural and Biological Sciences © 2015 Elsevier Ltd. All rights reserved. The electromechanical properties of graphene/gelatin hydrogel composites were investigated under the effects of graphene surface area, electric field strength and temperature towards bio-actuator applications. The highest surface area of an embedded graphene (MG; grade M) in the gelatin hydrogel composites induced the highest dynamic modulus (G′) under applied electric field. The 0.1 vol% graphene (MG)/gelatin hydrogel composite possessed the highest ΔG′/G′ < inf > o < /inf > value of 352% in comparison with other materials in previous studies. Even the lowest ΔG′/G′ < inf > o < /inf > values obtained from the fabricated graphene/hydrogel composites were still greater than other dielectric elastomer materials investigated. The storage moduli of the pure gelatin and graphene (MG)/gelatin hydrogel composites, between 30 °C and 90 °C, exhibited three distinct regimes. In the deflection experiment, the bending distance and the dielectrophoresis force were found to increase monotonically with applied electric field strength with a deflection toward the anode side, indicating the attractive force between the anode and the polarized carboxyl group as the gelatin structure possessed negative charges under applied electric field. 2018-01-24T04:40:36Z 2018-01-24T04:40:36Z 2015-06-30 Journal 00323861 2-s2.0-84933529388 10.1016/j.polymer.2015.06.027 https://www.scopus.com/inward/record.uri?partnerID=HzOxMe3b&scp=84933529388&origin=inward http://cmuir.cmu.ac.th/jspui/handle/6653943832/44307 |
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Agricultural and Biological Sciences Thawatchai Tungkavet Nispa Seetapan Datchanee Pattavarakorn Anuvat Sirivat Graphene/gelatin hydrogel composites with high storage modulus sensitivity for using as electroactive actuator: Effects of surface area and electric field strength |
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© 2015 Elsevier Ltd. All rights reserved. The electromechanical properties of graphene/gelatin hydrogel composites were investigated under the effects of graphene surface area, electric field strength and temperature towards bio-actuator applications. The highest surface area of an embedded graphene (MG; grade M) in the gelatin hydrogel composites induced the highest dynamic modulus (G′) under applied electric field. The 0.1 vol% graphene (MG)/gelatin hydrogel composite possessed the highest ΔG′/G′ < inf > o < /inf > value of 352% in comparison with other materials in previous studies. Even the lowest ΔG′/G′ < inf > o < /inf > values obtained from the fabricated graphene/hydrogel composites were still greater than other dielectric elastomer materials investigated. The storage moduli of the pure gelatin and graphene (MG)/gelatin hydrogel composites, between 30 °C and 90 °C, exhibited three distinct regimes. In the deflection experiment, the bending distance and the dielectrophoresis force were found to increase monotonically with applied electric field strength with a deflection toward the anode side, indicating the attractive force between the anode and the polarized carboxyl group as the gelatin structure possessed negative charges under applied electric field. |
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Thawatchai Tungkavet Nispa Seetapan Datchanee Pattavarakorn Anuvat Sirivat |
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Thawatchai Tungkavet Nispa Seetapan Datchanee Pattavarakorn Anuvat Sirivat |
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Thawatchai Tungkavet |
title |
Graphene/gelatin hydrogel composites with high storage modulus sensitivity for using as electroactive actuator: Effects of surface area and electric field strength |
title_short |
Graphene/gelatin hydrogel composites with high storage modulus sensitivity for using as electroactive actuator: Effects of surface area and electric field strength |
title_full |
Graphene/gelatin hydrogel composites with high storage modulus sensitivity for using as electroactive actuator: Effects of surface area and electric field strength |
title_fullStr |
Graphene/gelatin hydrogel composites with high storage modulus sensitivity for using as electroactive actuator: Effects of surface area and electric field strength |
title_full_unstemmed |
Graphene/gelatin hydrogel composites with high storage modulus sensitivity for using as electroactive actuator: Effects of surface area and electric field strength |
title_sort |
graphene/gelatin hydrogel composites with high storage modulus sensitivity for using as electroactive actuator: effects of surface area and electric field strength |
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2018 |
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https://www.scopus.com/inward/record.uri?partnerID=HzOxMe3b&scp=84933529388&origin=inward http://cmuir.cmu.ac.th/jspui/handle/6653943832/44307 |
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