A V3C2 MXene/graphene heterostructure as a sustainable electrode material for metal ion batteries

Individually, MXene and graphene based frameworks have been recognized as promising 2D electrode materials for metal ion batteries. Herein, we have engineered a heterostructure of V3C2 MXene and graphene using computational design. A comprehensive investigation of designed heterostructure has been reported in this work. Simulated heterostructure has been evaluated for various functionalities such as high performance of thermal stability, metal ion intercalation, diffusion energy using density functional theory method. Interestingly, simulation examinations and obtained calculations demonstrate the high storage capacity of Li and Ca (598.63 mAh g(-1)), and Na (555.87 mAh g(-1)) with the designed V3C2/graphene model. Promising diffusion energy barriers for Li (0.11 eV), Na (0.17 eV) and Ca (0.15 eV) ions are also investigated and have explained systematically in the present work. Moreover, we have achieved high capacity and fast charge/discharge rates of V3C2/graphene heterostructure indicating its promising electrode potential efficiency for ion batteries especially for Na ion battery. Thus, our investigation demonstrate the advantages of newly designed V3C2 MXene and graphene heterostructure for advance metal ion batteries.

Automated summary

A heterostructure of V3C2 MXene and graphene has been engineered using computational design, with promising performance in terms of storage capacity and diffusion energy barriers for Li, Na, and Ca ions. The findings suggest the potential efficiency of this heterostructure for advanced metal ion batteries, especially for Na ion batteries.