Effect of porous structural properties on lithium-ion and sodium-ion storage: illustrated by the example of a micro-mesoporous graphene(1−x)(MoS(2))(x) anode

In this work, we synthesized micro-mesoporous graphene(1−x)(MoS(2))(x) with different compositional ratios via co-reduction of graphite oxide and exfoliated MoS(2) platelets. We systematically studied the performance of the micro-mesoporous graphene(1−x)(MoS(2))(x) as anodes in lithium-ion batteries and sodium-ion batteries. The results show that the specific surface areas of the composites decrease with introducing MoS(2). The irreversible capacitance, which is related to the formation of solid electrolyte interphases, also decreases. Besides specific surface area, we found that micropores can benefit the lithiation and sodiation. We demonstrated that a specific charge capacity of 1319.02 mA h g(−1) can be achieved at the 50th cycle for the graphene(½)(MoS(2))(½) anode in lithium-ion batteries. Possible relationships between such a high specific capacity and the micro-mesoporous structure of the graphene(1−x)(MoS(2))(x) anode are discussed. This work may shed light on a general strategy for the structural design of electrode materials in lithium-ion batteries and sodium-ion batteries.