Sodium-Ion Hybrid Capacitor of High Power and Energy Density

[Image: see text] Sodium-ion hybrid capacitors (NHCs) have been attracting research interest in recent years. However, NHCs suffer from slower redox reaction kinetics of electrodes as compared to non-Faradaic capacitive counterparts. Herein, a high-performance NHC using porous NaBi as anode, activated carbon (AC) as cathode, and 1.5 M of NaPF(6) in diglyme as electrolyte is reported. In a charging process, Na(+) is inserted into NaBi to form Na(3)Bi, and PF(6)(–) is stored in the electric double layers of the AC cathode; in a reverse process, the Na(3)Bi is desodiated to NaBi and eventually Bi, and the adsorbed PF(6)(–) is released into the electrolyte in the first cycle. The NHC exhibits a capacity of ∼298 mA h g(Bi)(–1), capacity retention of 98.6% after 1000 cycles at 2 A g(Bi)(–1), and Coulombic efficiency of >99.4%. The achievable power and energy density are as high as 11.1 kW kg(total)(–1) and 106.5 W h kg(total)(–1), respectively. The superior electrochemical performance is ascribed to the gradually formed three-dimensional (3D) porous and stable networks of the anode, ensuring its comparable fast reaction kinetics and cycle stability to the AC cathode.