Paper
3 April 2012 Applications of scanned pipettes to the localized characterization of actuating conducting polymers: an SICM design for simultaneous ion flux and topography measurements
Karthik Kannappan, Cosmin Laslau, David E. Williams, Jadranka Travas-Sejdic
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Abstract
Recent applications of the scanned pipette to materials science problems have included its quantification of the ion flux resulting from conducting polymer actuation. However, in order to correlate this flux with the precise height changes arising from actuation, a separate experiment must be carried out. Herein we propose a new design that may be capable of simultaneously determining both ion flux and topography, on the basis of subtle current density magnitude shifts and precisely chosen experimental positioning parameters. A simulation of the geometrical model - consisting of the pipette, conducting polymer film and electrodes - was setup and solved in 2D axi-symmetrical domain. The ion concentrations, voltage potentials and current densities were determined as a function of time, with three key parameters varied: the maximum ion flux value Jmax, conducting polymer swelling Tp and overall separation distance d between pipette and polymer. It was found that the separation Tp - d should be around 50 to 150 nm, roughly the same as the actuation itself. Furthermore, the current density component arising from geometrical changes due to actuation was on the order of a few percent, and was highly sensitive to Jmax levels.
© (2012) COPYRIGHT Society of Photo-Optical Instrumentation Engineers (SPIE). Downloading of the abstract is permitted for personal use only.
Karthik Kannappan, Cosmin Laslau, David E. Williams, and Jadranka Travas-Sejdic "Applications of scanned pipettes to the localized characterization of actuating conducting polymers: an SICM design for simultaneous ion flux and topography measurements", Proc. SPIE 8340, Electroactive Polymer Actuators and Devices (EAPAD) 2012, 83400I (3 April 2012); https://doi.org/10.1117/12.917565
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KEYWORDS
Ions

Polymers

Actuators

Electrodes

Atomic force microscopy

Interfaces

Materials science

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