Mechanoionic Transduction of Solid Polymer Electrolytes and Potential Applications
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Mechanoionic Transduction of Solid Polymer Electrolytes and Potential Applications Yuta Dobashi1, Graham Allegretto1, Mirza S. Sarwar1, Edmond Cretu1 and John D.W. Madden1*
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Advanced Materials and Process Engineering Laboratory, Department of Electrical & Computer Engineering, University of British Columbia, Vancouver, BC V6T 1Z4 * E-Mail: [email protected]
ABSTRACT A novel pressure sensor is proposed exhibiting generative properties from displacement-induced ionic charge separation in gel electrolytes. A mechano-ionic or ‘piezo-ionic’ effect, in analogy to the well-known piezoelectric effect, is hypothesized to originate from a difference in mobilities between cationic and anionic species causing a localized ionic charge gradient upon application of pressure. This gradient can be detected as a voltage or current by using copper electrodes placed at the sides or at regular intervals along a surface of the gel. The voltage generated may be a result of the local concentration gradient induced by the deformation of the gel or perhaps is the result of some ions moving faster through the porous gel than others. In this work, ionic polymer gels based on Poly(vinylidene fluoride-hexafluoropropylene) (PVDF-HFP) co-polymer were synthesized in situ to incorporate an organic electrolyte consisting of bis(trifluoromethane)sulfonimide lithium salt in propylene carbonate. With two electrodes placed under the gel, the samples were subjected to a sinusoidal mechanical force while open circuit voltage was measured to determine the relationship between electrical signal and mechanical input. The voltages generated are 10’s of mV in magnitude at 1 kPa. Results suggest a maximum sensitivity of 25 μV/Pa at 10 mHz, comparable to the voltages expected in piezoelectric polymers such as PVDF (44 μV/Pa for similar dimensions). The non-aqueous, solid-state ionic gels presented in this work provide improved stability and is less prone to evaporation than its aqueous, hydrogel based counterpart. The new mechanism of sensing provides an alternative to the more rigid and less stretchable piezoelectric sensors. INTRODUCTION With increasing interest in the fields of soft robotics and wearable medical technologies, a demand for discrete tissue-like human-to-computer interfaces has evolved [1][2][3]. Sensors that are flexible, stretchable, and biocompatible are characteristics that many existing sensors lack. Ionic gels are a promising class of materials that can potentially bridge the gap between current sensor technologies and tomorrow’s soft-sensor requirements. Previous work by Sun et al created an “ionic skin” based on electrolyte swollen polyacrylamide Figure 1: Photograph of the solid acting as electrodes in a transparent capacitive polymer electrolyte based on PVDFdeformation sensor [4]. The gel used is extremely HFP loaded with 0.1M LiTFSI/PC. stretchable and tough, yet very compliant. It can be stretched by 20 times in length and has an elastic modulus of less than 1 MPa. In the work
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presented here, a similar material is utilized
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