Natural cellulose ionogels for soft artificial muscles

[Display omitted] •Preparation process for natural cellulose-ionic liquid ionogels actuators was investigated.•Reverse bending of actuators was detected already at ±500mV.•Mathematical model was introduced for a comprehensive understanding of bending actuation at various step input voltages. Rapid d...

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Bibliographic Details
Published in:Colloids and surfaces, B, Biointerfaces B, Biointerfaces, 2018-01, Vol.161, p.244-251
Main Authors: Nevstrueva, Daria, Murashko, Kirill, Vunder, Veiko, Aabloo, Alvo, Pihlajamäki, Arto, Mänttäri, Mika, Pyrhönen, Juha, Koiranen, Tuomas, Torop, Janno
Format: Article
Language:English
Subjects:
Actuator
Biomaterial
Cellulose
Ionic liquid
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Summary:[Display omitted] •Preparation process for natural cellulose-ionic liquid ionogels actuators was investigated.•Reverse bending of actuators was detected already at ±500mV.•Mathematical model was introduced for a comprehensive understanding of bending actuation at various step input voltages. Rapid development of soft micromanipulation techniques for human friendly electronics has raised the demand for the devices to be able to carry out mechanical work on a micro- and macroscale. The natural cellulose-based ionogels (CEL-iGEL) hold a great potential for soft artificial muscle application, due to its flexibility, low driving voltage and biocompatibility. The CEL-iGEL composites undergo reversible bending already at ±500mV step-voltage values. A fast response to the voltage applied and high ionic conductivity of membranous actuator is achieved by a complete dissolution of cellulose in 1-ethyl-3-methylimidazolium acetate [EMIm][OAc]. The CEL-iGEL supported cellulose actuator films were cast out of cellulose-[EMIm][OAc] solution via phase inversion in H2O. The facile preparation method ensured uniform morphology along the layers and stand for the high ionic-liquid loading in a porous cellulose scaffold. During the electromechanical characterization, the CEL-iGEL actuators showed exponential dependence to the voltage applied with the max strain difference values reaching up to 0.6% at 2 V. Electrochemical analysis confirmed the good stability of CEL-iGEL actuators and determined the safe working voltage value to be below 2.5V. To predict and estimate the deformation for various step input voltages, a mathematical model was proposed.
ISSN:0927-7765
1873-4367
DOI:10.1016/j.colsurfb.2017.10.053