Pseudocapacitive Charge Storage in Electrochromic Transition-Metal Oxide Thin Films
Dongmei Dong, Tinsley Elizabeth Benhaddouch, Christopher Lloyd Metler, John Marcial, Yaoli Zhao, Vagheeswari Venkadesh, Thomas Thundat, Shekhar Bhansali
Abstract
Electrochromic pseudocapacitive transition-metal oxide materials, such as tungsten oxide, which combine fast response, high energy density, and optical effects, can play a significant role as energy storage materials. Here we investigate the electrochemical kinetics of thin films of tungsten oxide, which turn transparent to sky-blue color in the lithiated state due to the reduction of W 6+ to W 5+ . We investigated the charge density, charge transfer, ion diffusion, and interfacial behavior upon Li + insertion/de-insertion in WO 3 . The electrochromic thin film’s pseudocapacitive and electrical double layer mechanism was differentiated based on the power-law. Faradaic diffusion-controlled process dominates over the surface capacitive behavior at scan rates below 40 mV s −1 . These films exhibit an areal charge density of around 100 mC cm −2 and a capacitance of 80 mF cm −2 , superior to most comparable electrochromic materials and supercapacitors. This work combines electrochromics and energy storage properties and provides a fundamental understanding of pseudocapacitive and electrochromic mechanisms in WO 3 .