Scalable flexible electrochromic devices with WO3-based ion storage layer for enhanced optical modulation and stability

Photo-electrochemical stability, rapid switching time, and mechanical durability are key factors in achieving high-performance flexible and large-area electrochromic (EC) devices. However, the typically used counter electrode of indium tin oxide (ITO) are prone to degradation after repeated redox cycling and reiterative bending stress. This study introduces a heterogeneous structure that incorporates modified poly(3,4ethylenedioxythiophene) (m-PEDOT) as the organic electrochromic material and a tungsten trioxide (WO3) film in the counter electrode of ITO, which serves as both an ion storage layer and a protective layer. The WO3based EC devices achieved a maximum optical modulation (Delta T) of 51 % at 631 nm, significantly higher than the 17 % (Delta T) observed in devices without WO3. Additionally, the device demonstrated fast switching times of 1.2 s for bleaching and 6.3 s for coloring, with a high coloring efficiency of 474 cm2/C. Durability tests revealed a 98 % recovery in optical modulation after 500 cycles, and strong mechanical stability after 100 bending cycles. The fabrication of a 1170 cm2 flexible device confirms the practical viability of this approach, enhancing both electrochemical and optical properties for large-scale applications such as smart windows.