Abstract

To explore the effect of sulfur vacancies in transition metal sulfide on the electrochemical properties of anode materials, the graphene oxide (GO) and CoNi 2 S 4 were used as the raw materials to synthesize the rGO 10 −CoNi 2 S 4− x composite electrode materials by the solvothermal method. The obtained rGO 10 −CoNi 2 S 4− x electrode materials with sulfur vacancies consist of nanoflakes and nanorods. The galvanostatic charge−discharge test of the rGO 10 −CoNi 2 S 4− x electrode materials shows a great specific capacitance of 3050.1 F/g at a current density of 1 A/g. Moreover, the electrode materials still remain rate capability retention of 86.1% when the current density increases from 1 to at 10 A/g. The rGO 10 −CoNi 2 S 4− x composite containing sulfur vacancies has higher specific capacitance and better rate capability in comparison to the pristine rGO−CoNi 2 S 4 without containing sulfur defects. The optimized rGO 10 −CoNi 2 S 4− x composite electrode materials with sulfur vacancies exhibit outstanding cycle stability and rate performance.