Abstract
Metallic sodium, which has a suitable redox potential and high theoretical capacity, is regarded as an ideal anode material for rechargeable Na metal batteries. However, dendrite growth on sodium metal during cycling has seriously restricted its practical applications. Herein, we employed a low-cost and facile brushing method to fabricate a porous nano-SiO(2) coating, which can induce a relatively uniform distribution of Na(+) flux and suppress the growth of Na dendrites. The nano-SiO(2) coating with high porosity can decrease the Na stripping/plating overpotential (<50 mV) over 400 cycles at 5 mA cm(-2). Moreover, when coupled with a Na(3)V(2)(PO(4))(3) (NVP) cathode, the Na with SiO(2) coating (Na@SiO(2)) composite anode shows a favorable suitability in a full cell. Compared with the one with a bare Na anode, the full cell with the Na@SiO(2) anode delivers a 27.8% higher discharge capacity (94.6 vs. 74 mA h g(-1) at 1C) after 1000 cycles.