Abstract

Polyanion materials are promising candidates for new rechargeable battery electrodes due to their good capacity, operation voltage, safety characteristics, as well as low cost. A family of materials based on metal hydroxysulfate or hydroxyphosphate naturally occurring minerals offers the possibility for improved performance as cathode materials due to the following characteristics: (1) open framework or layered structures that can facilitate fast Li+ insertion, (2) flexibility in alkali and transition metal cation incorporation as observed in nature, which can allow for the design of solid-solutions to enhance structural stability, capacity, and reaction potentials, and (3) possibility for multi-electron redox reactions, which can result in capacities >200 mAh/g. This presentation will introduce our investigation into nanostructured brochantite and jarosite minerals for use as electrodes in Li-ion and Na-ion batteries. The electrochemical properties of brochantite, Cu4(OH)6SO4, a natural mineral and patina constituent on the Statue of Liberty, were investigated. Nanostructured brochantite was synthesized using precipitation and microwave-assisted hydrothermal reactions and evaluated in half-cells with Li metal counter electrodes. Reversible capacities >400 mAh/g corresponding to the 2 electron reduction of Cu2+ and discharge potential of 1.8 V versus Li/Li+ were observed in brochantite with a nanoplate morphology. The electrochemical properties of the jarosite and V3+ jarosite analogue compounds, MN3(SO4)2(OH)6, where M=K, Na and N=Fe, V, were also investigated. A common industrial mining waste byproduct and naturally occurring mineral on Earth and Mars, the jarosite structure can accommodate many different cations and may serve as a good starting point for developing cathodes for batteries beyond Li-ion. Microstructured jarosites were synthesized using microwave-assisted hydrothermal reaction and the electrochemical characteristic were evaluated in half-cells with Li and Na metal. Detailed characterization using X-ray diffraction, scanning and transmission electron microscopy, and X-ray photoelectron spectroscopy was performed to better understand the structural changes and reaction mechanisms in both brochantite and jarosite systems. Reference: R. Zhao, T. Yang, M.A. Miller, C.K. Chan, Nano Lett., 13, 6055 – 6063 (2013).

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