posted on 2017-10-27, 00:00authored byRanjith Thangavel, Amaresh Samuthira Pandian, Hari Vignesh Ramasamy, Yun-Sung Lee
The
abundance of sodium resources has recently motivated the investigation
of sodium ion batteries (SIBs) as an alternative to commercial lithium
ion batteries. However, the low power and low capacity of conventional
sodium anodes hinder their practical realization. Although most research
has concentrated on the development of high-capacity sodium anodes,
anodes with a combination of high power and high capacity have not
been widely realized. Herein, we present a simple microwave irradiation
technique for obtaining few-layered, ultrathin two-dimensional SnS2 over graphene sheets in a few minutes. SnS2 possesses
a large number of active surface sites and exhibits high-capacity,
rapid sodium ion storage kinetics induced by quick, nondestructive
pseudocapacitance. Enhanced sodium ion storage at a high current density
(12 A g–1), accompanied by high reversibility and
high stability, was demonstrated. Additionally, a rationally designed
sodium ion full cell coupled with SnS2//Na3V2(PO4)3 exhibited exceptional performance
with high initial Coulombic efficiency (99%), high capacity, high
stability, and a retention of ∼53% of the initial capacity
even after the current density was increased by a factor of 140. In
addition, a high specific energy of ∼140 Wh kg–1 and an ultrahigh specific power of ∼8.3 kW kg–1 (based on the mass of both the anode and cathode) were observed.
Because of its outstanding performance and rapid synthesis, few-layered
SnS2 could be a promising candidate for practical realization
of high-power SIBs.