posted on 2017-08-14, 14:48authored byKara D. Fong, Tiesheng Wang, Hyun-Kyung Kim, R. Vasant Kumar, Stoyan K. Smoukov
Conducting polymers show great promise as supercapacitor materials
due to their high theoretical specific capacitance, low cost, toughness,
and flexibility. Poor ion mobility, however, can render active material
more than a few tens of nanometers from the surface inaccessible for
charge storage, limiting performance. Here, we use semi-interpenetrating
networks (sIPNs) of a pseudocapacitive polymer in an ionically conductive
polymer matrix to decrease ion diffusion length scales and make virtually
all of the active material accessible for charge storage. Our freestanding
poly(3,4-ethylenedioxythiophene)/poly(ethylene oxide) (PEDOT/PEO)
sIPN films yield simultaneous improvements in three crucial elements
of supercapacitor performance: specific capacitance (182 F/g, a 70%
increase over that of neat PEDOT), cycling stability (97.5% capacitance
retention after 3000 cycles), and flexibility (the electrodes bend
to a <200 μm radius of curvature without breaking). Our simple
and controllable sIPN fabrication process presents a framework to
develop a range of polymer-based interpenetrated materials for high-performance
energy storage technologies.