Fast Proton Insertion in Layered H₂W₂O₇ via Selective Etching of an Aurivillius Phase Article Swipe

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Materials science Electrochromism Raman spectroscopy Density functional theory Graphene Analytical Chemistry (journal) Proton transport Proton Nanotechnology Electrode Physical chemistry Optics Chemistry Computational chemistry Chromatography Quantum mechanics Physics

Ruocun Wang , Yangyunli Sun , Alexander B. Brady , Simon Fleischmann , Tim B. Eldred , Wenpei Gao , Hsiu‐Wen Wang , De‐en Jiang , Veronica Augustyn ·

YOU? · · 2020 · Open Access · · DOI: https://doi.org/10.1002/aenm.202003335 · OA: W3108690810

H 2 W 2 O 7 , a metastable material synthesized via selective etching of the Aurivillius‐related Bi 2 W 2 O 9 , is demonstrated as an electrode for high power proton‐based energy storage. Comprehensive structural characterization is performed to obtain a high‐fidelity crystal structure of H 2 W 2 O 7 using an iterative approach that combines X‐ray diffraction, neutron pair distribution function, scanning transmission electron microscopy, Raman spectroscopy, and density functional theory modeling. Electrochemical characterization shows a capacity retention of ≈80% at 1000 mV s –1 (1.5‐s charge/discharge time) as compared to 1 mV s –1 (≈16‐min charge/discharge time) with cyclability for over 100 000 cycles. Energetics from density functional theory calculations indicate that proton storage occurs at the terminal oxygen sites within the hydrated interlayer. Last, optical micrographs collected during in situ Raman spectroscopy show reversible, multicolor electrochromism, with color changes from pale yellow to blue, purple, and last, orange as a function of proton content. These results highlight the use of selective etching of layered perovskites for the synthesis of metastable transition metal oxide materials and the use of H 2 W 2 O 7 as an anode material for proton‐based energy storage or electrochromic applications.