AVS 66th International Symposium & Exhibition
    2D Materials Thursday Sessions
       Session 2D+AS+BI+HC+MN+NS+PS+SS+TL-ThA

Paper 2D+AS+BI+HC+MN+NS+PS+SS+TL-ThA8
Proton Conductivity Properties of Electrospun Chitosan Nanofibers

Thursday, October 24, 2019, 4:40 pm, Room A216

Session: Surface Chemistry, Functionalization, Bio, Energy and Sensor Applications
Presenter: Woo-Kyung Lee, U.S. Naval Research Laboratory
Authors: W.-K. Lee, U.S. Naval Research Laboratory
J.J. Pietron, U.S. Naval Research Laboratory
D.A. Kidwell, U.S. Naval Research Laboratory
J.T. Robinson, U.S. Naval Research Laboratory
C.L. McGann, U.S. Naval Research Laboratory
S.P. Mulvaney, U.S. Naval Research Laboratory
Correspondent: Click to Email
A major challenge of the 21st century will be to establish meaningful two-way communication between biology and electronics. The study of protonics, devices that mimic electronics but pass protons instead of electrons, seeks to bridge this gap. Protonic conductive materials (PCMs) are essential elements of these devices and we have demonstrated significant improvement in conductivity for chitosan PCMs when deposited as electrospun nanofibers. The observed improvements stem from both enhanced molecular alignment and from chemical doping due to the electrospinning carrier fluid, trifluoroacetic acid (TFA). We deposited electrospun chitosan nanofibers over palladium protodes and then used the helium ion microscope to isolate single nanofibers for detailed study. We observed that single chitosan nanofibers are strongly doped by TFA with x-ray photoelectron spectroscopy demonstrating extensively protonated nitrogen functionality. With the isolated, single chitosan nanofibers we observed that water uptake, fiber/electrode contact area, and doping concentration are critical parameters of protonic device performance and lead to increased conductivity (i.e. low resistivity). The average resistivity of single chitosan nanofibers is 6.2×104 Ω·cm, approximately two orders of magnitude lower than the resistivity of cast chitosan PCMs (cast from acetic acid solutions not TFA).We have observed excellent agreement between theoretical models and experiment results that explore each of the contributions to the improved conductivity. In addition, the fabrication and measurement of ionic field-effect transistor of single chitosan fiber using conductive atomic force microscope will be discussed.