Surface Fluorination for the Stabilization in Air of Garnet-Type Oxide Solid Electrolyte for Lithium Ion Battery Article Swipe

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Electrolyte Battery (electricity) Materials science Ion Lithium (medication) Oxide Inorganic chemistry Lithium-ion battery Chemical engineering Electrode Chemistry Metallurgy Organic chemistry Engineering Power (physics) Quantum mechanics Physical chemistry Endocrinology Physics Medicine

Michael Herraiz , Saida Moumen , Kévin Lemoine , Laurent Jouffret , Katia Guérin , Elodie Petit , Nathalie Gaillard , Laure Bertry , Rita Tóth , Thierry Le Mercier , Valérie Buissette , Marc Dubois ·

YOU? · · 2025 · Open Access · · DOI: https://doi.org/10.3390/batteries11070268 · OA: W4412477523

After reviewing the state of the art of the fluorination of inorganic solid electrolytes, an application of gas/solid fluorination is given and how it can be processed. Garnet-type oxide has been chosen. These oxides with an ideal structure of chemical formula A3B2(XO4)3 are mainly known for their magnetic and dielectric properties. Certain garnets may have a high enough Li+ ionic conductivity to be used as solid electrolyte of lithium ion battery. The surface of LLZO may be changed in contact with the moisture and CO2 present in the atmosphere that results in a change of the conductivity at the interface of the solid. LiOH and/or lithium carbonate are formed at the surface of the garnet particles. In order to allow for handling and storage under normal conditions of this solid electrolyte, surface fluorination was performed using elemental fluorine. When controlled using mild conditions (temperature lower or equal to 200 °C, either in static or dynamic mode), the addition of fluorine atoms to LLZO with Li6,4Al0,2La3Zr2O12 composition is limited to the surface, forming a covering layer of lithium fluoride LiF. The effect of the fluorination was evidenced by IR, Raman, and NMR spectroscopies. If present in the pristine LLZO powder, then the carbonate groups disappear. More interestingly, contrary to the pristine LLZO, the contents of these groups are drastically reduced even after storage in air up to 45 days when the powder is covered with the LiF layer. Surface fluorination could be applied to other solid electrolytes that are air sensitive.