Highly Crystalline WO3 Thin Films with Ordered 3D Mesoporosity and Improved Electrochromic Performance

WO3 thin layers with nanometer‐scale periodicity were prepared by evaporation‐induced self‐assembly (EISA) using a novel amphiphilic block‐copolymer template (poly(ethylene‐co‐butylene)‐block‐poly(ethylene oxide)). The evolution of the mesoporous ordered network and the crystallinity of the framework were monitored by 2D‐SAXS, WAXS, SEM, XPS, and porosimetry. By annealing the films, the pore‐wall crystallinity is adjusted between fully amorphous and highly crystalline without mesostructural degradation. Thus, the crystalline‐film framework is composed of phase‐pure monoclinic WO3 nanoparticles (12–14 nm in size). Furthermore, heat treatment transforms the originally spherical mesopores into ellipsoids, resulting in a unidirectionally shrunken, but still well‐defined and fully accessible bcc mesopore architecture. The influence of mesoporosity and crystallinity on electrochemical/electrochromic characteristics was addressed by monitoring electrochemical features and the absorption changes during Li insertion/extraction (repetitive potentiostatic cycling). Both the amorphous and crystalline mesoporous films possess electrochromic response times on the order of only seconds, which are attributable to the facilitated insertion of guest ions due to shortening of the diffusion path lengths. Also, the insertion/extraction reversibility of crystalline WO3 layers with 3D mesoporosity is improved compared to amorphous ones and reaches values close to 100 %. Pores for effects: WO3 thin films with nanometer‐scale periodicity and a highly crystalline framework were obtained by sol‐gel templating using suitable templates and appropriate preparation conditions. These materials revealed an improved electrochemical/electrochromic performance (in terms of response times, cycling stability, etc.) due to the favorable combination of 3D mesoporosity and crystallinity.