Improvement in cycling stability of Prussian blue analog-based aqueous sodium-ion batteries by ligand substitution and electrolyte optimization

In this study, we investigated the effects of ligand substitution in Prussian blue analog (PBA) cathode materials on the performance of aqueous sodium-ion batteries. NaCu[Fe(CN)(6)] (NaCuHCF) and ligand-modified PBAs, NaxCu[Fe(CN)(5)(C6H4N2)] (NaxCuCNPFe), and NaxCu[Fe(CN)(5)(CH3C6H4NH2)] (Na(x)CuTolFe) were tested in different electrolytes. The NaxCuCNPFe and Na(x)CuTolFe cathodes exhibited the best capacity retention of similar to 50% after 2000 cycles in 1 M Na2SO4, which is much higher than that of the NaCuHCF cathode (0% capacity remained after 2000 cycles). To understand the charge-discharge mechanism of PBA cathodes, in situ synchrotron X-ray absorption spectroscopy and X-ray diffraction were performed. To demonstrate practical energy storage appli-cations, PBAs were tested in full-cell configurations with an anode made of sodium titanium phosphate (NTP) coated with reduced graphene oxide and carbon (NTP@C@RGO). The NaxCuCNPFe//NTP@C@RGO and Na-x-CuTolFe//NTP@C@RGO full cells in 17 m NaClO4 aqueous electrolyte exhibited high power densities of up to 4338 W kg(-1) (with an energy density of 18.11 Wh kg(-1)) and 4742 W kg(-1) (with an energy density of 11.87 Wh kg(-1)), respectively. Our study demonstrates the potential of optimizing organic ligands in PBAs and electrolytes for the improvement of the cycling stability of high-power aqueous sodium-ion batteries.