Macmillan Publishers Limited. / Nikon / Molecular Science Laboratory / Sigma-Aldrich / McGraw-Hill / Dupont / Hajimolana S. A. / Creative Commons / Northwest National Laboratory / Battelle for DOE / /
Country
Germany / United States / / /
Facility
Northwest National Laboratory / Pacific Northwest National Laboratory / /
IndustryTerm
aqueous methanol solutions / large-scale energy storage / energy industry / system energy density / energy storage market / high energy retention / high-energy density / stationary energy storage / chemical shift / discharge energy density / high energy density / charge carrier / electrochemical energy storage / metal electrode / energy density / achievable energy density / energy density value / high-energy density aqueous redox / chemical shift evolution / solvation free energy / intermittent renewable energy integration / metal ions / aqueous solution / energy density o10 / discharge energy densities / stationary applications / ow-based electrochemical energy storage systems / energy / theoretical energy density / metal / low energy density / zinc iodide solutions / energy-bearing redox active species / zinc metal / energy storage / water solutions / monotonous chemical shift / specific energy density / metal iodide iodine systems / high-energy density aqueous zinc-polyiodide / on-line cycling test / significant chemical shift / energy storage applications / energy densities / chemical shifts / actual energy density / Energy storage systems / energy losses / energy efficiency / potential energy surface / aqueous solutions / metal counter cation / battery systems / charged catholyte solution / lower energy barrier / energy output / grid-scale energy storage applications / observed demonstrating the high energy retention / /
Organization
Pacific Northwest National Laboratory / U.S. Department of Energy / Energy and Environment Directorate / /
ARTICLE Received 24 Oct 2014 | Accepted 14 Jan 2015 | Published 24 Feb 2015 DOI: [removed]ncomms7303 OPEN