Enhanced Performance of KVPO 4 F 0.5 O 0.5 in Potassium Batteries by Carbon Coating Interfaces.
Louiza LarbiRomain WernertPhilippe FiouxLaurence CroguennecLaure MonconduitCamélia Matei GhimbeuPublished in: ACS applied materials & interfaces (2023)
Potassium vanadium oxyfluoride phosphate of composition KVPO 4 F 0.5 O 0.5 was modified by a carbon coating to enhance its electrochemical performance. Two distinct methods were used, first, chemical vapor deposition (CVD) using acetylene gas as a carbon precursor and second, an aqueous route using an abundant, cheap, and green precursor (chitosan) followed by a pyrolysis step. The formation of a 5 to 7 nm-thick carbon coating was confirmed by transmission electron microscopy and it was found to be more homogeneous in the case of CVD using acetylene gas. Indeed, an increase of the specific surface area of one order of magnitude, low content of C sp 2 , and residual oxygen surface functionalities were observed when the coating was obtained using chitosan. Pristine and carbon-coated materials were compared as positive electrode materials in potassium half-cells cycled at a C/5 (C = 26.5 mA g -1 ) rate within a potential window of 3 to 5 V vs K + /K. The formation by CVD of a uniform carbon coating with the limited presence of surface functions was shown to improve the initial coulombic efficiency up to 87% for KVPFO 4 F 0.5 O 0.5 -C 2 H 2 and to mitigate electrolyte decomposition. Thus, performance at high C-rates such as 10 C was significantly improved, with ∼50% of the initial capacity maintained after 10 cycles, whereas a fast capacity loss is observed for the pristine material.