Well-defined electrochemical switching of amphiphilic glycolated poly(3,4-ethylenedioxythiophene)

The approach of using polyether, aka glycol, side chains to afford amphiphilicity to conducting polymers has recently emerged as a powerful technique for next-generation materials for bioelectronics and electrochemical devices. Herein we apply this synthetic logic to the archetypical conducting polymer poly(3,4-ethylenedioxythiophene), PEDOT, to generate a glycolated PEDOT analogue, G-PEDOT. We report on the electropolymerization of this material, and its electrochemical properties: including spectroelectrochemistry, electrochemical capacitance, and operation of microelectrodes and electrochemical transistors. While in many respects performing like PEDOT, G-PEDOT has electrochemical switching within lower potentials with complete de-doping at lower potentials, affording transistors with higher on/off ratios than PEDOT, and electrochromic switching within a smaller electrochemical window. Overall, G-PEDOT emerges as a useful, functional alternative to other PEDOT derivatives, and could be a building block in copolymers.

Automated summary

The use of polyether side chains to introduce amphiphilicity to conducting polymers has been applied to the synthesis of glycolated PEDOT. G-PEDOT exhibits improved electrochemical switching and electrochromic properties compared to PEDOT, making it a functional alternative for use in bioelectronics and electrochemical devices.