Constructing Hierarchical Porous MoO @Mo N@C Composite via a Confined Pyrolysis Synthetic Strategy Towards Lithium-Ion Battery Anodes.

Molybdenum dioxide (MoO ) demonstrates a big potential toward lithium-ion storage due to its high theoretical capacity. The sluggish reaction kinetics and large volume change during cycling process, however, unavoidably lead to inferior electrochemical performance, thus failing to satisfy the requirements of practical applications. Herein, we developed a molybdenum-based oxyacid salt confined pyrolysis strategy to achieve a novel hierarchical porous MoO @Mo N@C composite. A two-step successive annealing process was proposed to obtain a hybrid phase of MoO and Mo N, which was used to further improve the electrochemical performance of MoO -based anode. We demonstrate that the well-dispersed MoO nanoparticles can ensure ample active sites exposure to the electrolyte, while conductive Mo N quantum dots afford pseudo-capacitive response, which conduces to the migration of ions and electrons. Additionally, the interior voids could provide buffer spaces to surmount the effect of volume change, thereby avoiding the fracture of MoO nanoparticles. Benefiting from the aforesaid synergies, the as-obtained MoO @Mo N@C electrode demonstrates a striking initial discharge capacity (1760.0 mAh g at 0.1 A g ) and decent long-term cycling stability (652.5 mAh g at 1.0 A g ). This work provides a new way for the construction of advanced anode materials for lithium-ion batteries.