Electrolyte Design with Dual –C≡N Groups Containing Additives to Enable High-Voltage Na<sub>3</sub>V<sub>2</sub>(PO<sub>4</sub>)<sub>2</sub>F<sub>3</sub>-Based Sodium-Ion Batteries
Mingqin Jiang, Tianyu Li, Yanling Qiu, Xin Hou, Hongzhen Lin, Qiong Zheng, Xianfeng Li
Abstract
Na 3 V 2 (PO 4 ) 2 F 3 is recognized as a promising cathode for high energy density sodium-ion batteries due to its high average potential of ∼3.95 V (vs Na/Na + ). A high-voltage-resistant electrolyte is of high importance due to the long duration of 4.2 V (vs Na/Na + ) when improving cyclability. Herein, a targeted electrolyte containing additives with two –C≡N groups like succinonitrile has been designed. In this design, one –C≡N group is accessible to the solvation sheath and enables the other –C≡N in dinitrile being exposed and subsequently squeezed into the electric double layer. Then, the squeezed –C≡N group is prone to a preferential adsorption on the electrode surface prior to the exposed –CH 2 /–CH 3 in Na + -solvent and oxidized to construct a stable and electrically insulating interface enriched CN – /NCO – /Na 3 N. The Na 3 V 2 (PO 4 ) 2 F 3 -based sodium-ion batteries within a high-voltage of 2–4.3 V (vs Na/Na + ) can accordingly achieve an excellent cycling stability (e.g., 95.07% reversible capacity at 1 C for 1,5-dicyanopentane and 98.4% at 2 C and 93.0% reversible capacity at 5 C for succinonitrile after 1000 cycles). This work proposes a new way to design high-voltage electrolytes for high energy density sodium-ion batteries.