Abstract
Graphene-like structure of V2O3 had been synthesized by a top-down precursor-pyrolyzation strategy. The first-order transformation of V2O3 disappeared with the increasing of temperature. It represents a positive temperature coefficient semiconductor behavior. It is a noteworthy and promising candidate for ultrathin energy-storage devices. The discharge capacity of V2O3 nanosheets is maintained at 300mAh/g after 75 cycles at the current density of 200mA/g, which exhibits excellent discharge capacity and superior cycling stability. Flower-like precursors composed of nanosheets were also successfully synthesized by adjusting temperature and time. V2O3 has perfectly inherited the morphology of its precursors. The new method demonstrated here provides a new way in the preparation of other ultrathin nanosheets materials.
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