Stoichiometrically Optimized Electrochromic Complex [V2o2+ξ(oh)3-Ξ] Based Electrode: Prototype Supercapacitor with Multicolor Indicator

The systematic structure modification of metal oxides is becoming more attractive, and effective strategies for structural tunning are highly desirable for improving their practical color-modulating energy storage performances. Here, the ability of a stoichiometrically tuned oxide-hydroxide complex of porous vanadium oxide, namely [V2O2+xi(OH)(3-xi)](xi = 0:3) for multifunctional electrochromic supercapacitor application is demonstrated. Theoretically, the pre-optimized oxide complex is synthesized using a simple wet chemical etching technique in its optimized stoichiometry [V2O2+xi(OH)(3-xi)] with xi = 0, providing more electroactive surface sites. The multifunctional electrode shows a high charge storage property of 610 Fg(-1) at 1A g(-1), as well as good electrochromic properties with high color contrast of 70% and 50% at 428 and 640 nm wavelengths, faster switching, and high coloration efficiency. When assembled in a solid-state symmetric electrochromic supercapacitor device, it exhibits an ultrahigh power density of 1066 mWcm(-2), high energy density of 246 mWhcm(-2), and high specific capacitance of 290 mFcm(-2) at 0.2 mAcm(-2). A prepared prototype device displays red when fully charged, green when half charged, and blue when fully discharged. A clear evidence of optimizing the multifunctional performance of electrochromic supercapacitor by stoichiometrical tuning is presented along with demonstrating a device prototype of a 25 cm(2) large device for real-life applications.