Encapsulating N-Doped Carbon Nanorod Bundles/MoO Nanoparticles via Surface Growth of Ultrathin MoS Nanosheets for Ultrafast and Ultralong Cycling Sodium Storage.

Conversion-type anode materials possess high theoretical capacity for sodium-ion batteries (SIBs), owing to multi-electron transmission (2-6 electrons). Mo-based chalcogenides are a class of great promise, high-capacity host materials, but their development still undergoes serious volume changes and low transport kinetics during the cycling process. Here, MoO nanoparticles anchored on N-doped carbon nanorod bundles (N-CNRBs/MoO) are synthesized by a facile self-polymerized route and a following annealing. After hydrothermal sulfuration, N-CNRBs/MoO composites are encapsulated by surface growth of ultrathin MoS nanosheets, acquiring hierarchical N-CNRBs/MoO@MoS composites. Serving as the SIB anode, the N-CNRBs/MoO@MoS electrode exhibits significantly improved sodium-ion storage properties. The reversible capacity is up to 554.4 mA h g at 0.05 A g and maintains 249.3 mA h g even at 10.0 A g. During 5000 cycles, no obvious capacity decay is observed and the reversible capacities retain 334.8 mA h g at 3.0 A g and 301.4 mA h g at 5.0 A g. These properties could be ascribed to the vertical encapsulation of MoS nanosheets on high-crystalline N-CNRBs/MoO substrates. The hierarchical architecture and unique heterostructure between MoO and MoS synergistically facilitate sodium-ion diffusion, relieve volume changes, and boost pseudocapacitive charge storage of N-CNRBs/MoO@MoS electrode. Therefore, the rational growth of nanosheets on complex substrates shows promising potential to construct anode materials for high-performance batteries.