Fluorination/Defluorination Behavior of Y<sub>2</sub>C in Fluoride-Ion Battery Anodes
Takeshi Tojigamori, Naoki Matsui, Kota Suzuki, Masaaki Hirayama, Takeshi Abe, Ryoji Kanno
Abstract
High Resolution Image Download MS PowerPoint Slide Despite the high theoretical energy density of fluoride-ion batteries (FIBs), their practical applications are hindered by the large volume changes associated with the redox reactions (typically metal ↔ metal fluoride interconversions) of most of the corresponding anode materials. Consequently, FIB anode materials that react at low potentials with small expansion and shrinkage are desired. Inspired by the low theoretical volume change (8%) of the Y 2 C ↔ Y 2 CF 2 interconversion, we herein evaluated Y 2 C as an FIB anode material and determined its initial discharge and charge capacities as 565 and 432 mAh g –1, respectively. The first fluorination was characterized by a capacity plateau equivalent to a two-electron reaction at −2 V vs Pb/PbF 2 . The first and second halves of this region corresponded to the Y 2 C → Y 2 CF 2 intercalation reaction and Y 2 CF 2 lattice expansion, respectively, whereas further fluorination led to a YF 3 -like structure. Y 2 CF 2 formed at the end of the first plateau was reversibly defluorinated to Y 2 C upon charging. The reversible change in the shape of the C K-edge electron energy loss spectrum during charge–discharge indicated the contribution of carbon to the redox reaction. Thus, this paper presents, for the first time, an account of the reversible electrochemical intercalation of fluoride ions in FIB anode materials, paving the way for FIB commercialization.