Investigations toward a Non-Aqueous Hybrid Redox-Flow Battery with a Manganese-Based Anolyte and Catholyte
| Autor: | Benedikt Burgenmeister, Ingo Krossing, Sebastian Riedel, Burkhard Butschke, Tyler A. Gully, Karsten Sonnenberg, Joey Disch, Benjamin Schmidt, Kolja Bromberger, Maximilian Schmucker, Alexei Schmidt |
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| Rok vydání: | 2021 |
| Předmět: |
Materials science
Aqueous solution Renewable Energy Sustainability and the Environment non-aqueous Inorganic chemistry redox-flow batteries chemistry.chemical_element Manganese Flow battery Redox chemistry catholytes manganese General Materials Science anolytes 500 Naturwissenschaften und Mathematik::540 Chemie::540 Chemie und zugeordnete Wissenschaften |
| DOI: | 10.17169/refubium-31143 |
| Popis: | A new all-Manganese flow battery (all-MFB) as a non-aqueous hybrid redox-flow battery is reported. The discharged active material [Cat]2[MnIICl4] (Cat = organic cation) utilized in both half-cells supports a long cycle life. The reversible oxidation of [MnIICl4]2− to [MnIIICl5]2− at the positive electrode and manganese metal deposition from [MnIICl4]2− at the negative electrode give a cell voltage of 2.59 V. Suitable electrolytes are prepared and optimized, followed by a characterization in static battery cells and in a pumped flow-cell. Several electrode materials, solvents, and membranes are tested for their feasibility in the all-MFB. An electrolyte consisting of [EMP]2[MnCl4] and some solvent γ-butyrolactone is cycled 500 times, both in a static as well as a flow-cell, over a period of two months, with coulombic efficiencies up to 83%. With the electrolytes prepared in this work, energy densities up to 74 Wh L−1 are possible, exceeding the VRFB benchmark system, using solely the cheap and abundant element manganese as the active material. Although further optimizations are necessary, this system represents a new and promising setup toward sustainable stationary energy storage. |
| Databáze: | OpenAIRE |
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