Transition-metal
dichalcogenides (TMDs), a two-dimensional (2D)
nanostructured material, has, to a greater extent, technological applications
in catalysis, sensors, lithium-ion batteries, and optoelectronic devices
due to their unique structure and electrical properties. Recently,
the 2D TMD tungsten disulfide (WS2) has been regarded as
one of the most promising anode candidates for lithium-ion batteries.
However, the exploration of the WS2 sheets with the 1T
metallic phase still remains a prodigious challenge to improve its
conductivity and cycling stability in the application of lithium-ion
batteries. In this work, the highly rich 1T few-layered WS2 nanoflowers (referred to as rich 1T WS2 NFs) were synthesized,
exhibiting a rich 1T metallic phase with few-layered structures around
the active edge sites of the NFs for achieving a fast electron/ion
transfer, thereby delivering the enhanced cycling performance and
lithium storage. The rich 1T WS2 NFs exhibits an irreversible
capacity (charge capacity) of 810 mA h g–1 at 0.2
C, and after five cycles the average reversible capacity (discharge
capacity) exhibits 609, 577, 554, 542, 530, and 504 mA h g–1, with the increased c-rates of 0.4, 0.6, 0.8, 1, 1.5, and 2.0 C,
respectively. In addition, the rich 1T WS2 NFs anode without
additional carbon support exhibits an initial capacity of 890 mA h
g–1 and still remains at a capacity of 390 mA h
g–1 after 500 cycles, being better than the 2H WS2 NFs and the bulk WS2 sheets. This excellent rate
of performance is further attributed to the rich 1T metallic nature
of the few-layered WS2 NFs that could well-promote the
excellent cycling stability and rate capability in contrast to the
carbon free (i.e., graphene, CNTs) composites. More importantly, the
enlarged interlayer spacing (i.e., 0.67 nm) and its rich 1T metallic
nature are beneficial for the high capacity and improved long cycling
stability and thus makes a potential candidate for the superior Li-ion
storage anodes.
