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Roschning, Benedikt [Author]; Weißmüller, Jörg [Author] ; 866918418!, Technische Universität Hamburg Institut für Werkstoffphysik und Werkstofftechnologie, SFB 986 Maßgeschneiderte Multiskalige Materialsysteme M3

Stress-charge coupling coefficient for thin-film polypyrrole actuators

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  • Media type: E-Article
  • Title: Stress-charge coupling coefficient for thin-film polypyrrole actuators : investigation of capacitive ion exchange in the oxidized state
  • Contributor: Roschning, Benedikt [Author]; Weißmüller, Jörg [Author]
  • Corporation: 866918418! ; Technische Universität Hamburg, Institut für Werkstoffphysik und Werkstofftechnologie ; SFB 986 Maßgeschneiderte Multiskalige Materialsysteme M3
  • Published: 2019
  • Published in: Electrochimica acta ; 318(2019), Seite 504-512
  • Language: English
  • DOI: 10.15480/882.2307; 10.1016/j.electacta.2019.05.166
  • Identifier:
  • Keywords: Polypyrrole ; Actuation ; Stress-charge coupling ; Strain-charge coupling ; Plane stress
  • Origination:
  • Footnote: Sonstige Körperschaft: Technische Universität Hamburg
    Sonstige Körperschaft: Technische Universität Hamburg, Institut für Werkstoffphysik und Werkstofftechnologie
    Sonstige Körperschaft: Technische Universität Hamburg, SFB 986 Maßgeschneiderte Multiskalige Materialsysteme M3
  • Description: This work quantifies the actuation behavior of thin electrodeposited polypyrrole films on rigid substrates. During in situ cantilever bending experiments in aqueous perchloric acid, the films remain clamped to their substrate and the film stress is inferred from a small bending of the cantilever. The potential range under study is 0.4–0.8 V versus the standard hydrogen electrode. Within this potential region, the film is in the oxidized state and the actuation arises from capacitive electrode processes. For the volumetric capacitance, c*, we find 0.24±0.01F/mm3. The stress-charge coupling coefficient, ξ, which is defined as the stress variation per volumetric charge density, emerges as −153±11mV. The results are robust, reproducible and independent of the film thickness or the potential scan rate. The experimental value of ξ is supported by an independent estimate, based on a micromechanical model in combination with literature data for the partial molar volume of solvated perchlorate anions and the elastic constants of polypyrrole.
  • Access State: Open Access