In recent decades, tremendous attention has been paid to the development of new electrode materials with high capacitance to meet the requirements of electrode materials in supercapacitors. Among vanadium oxides, VO(A) has recently received increasing attention due to its unique layered structure, phase transformation and applications in Li-ion batteries. However, few studies have focused on the electrochemical properties of VO(A) as electrochemical capacitors. Herein, we develop a facile hydrothermal method to prepare VO(A)@C core-shell structured composites by carbonization of glucose in the presence of VO nanowires. The electrochemical properties of the VO(A)@C core-shell composites are investigated as a supercapacitor electrode material for the first time; the composites show excellent pseudocapacitive behavior and display a specific capacitance as high as 179 F g at 1 A g. A flexible asymmetric supercapacitor device is fabricated using VO(A)@C composites and activated carbon and delivers an excellent capacitance of 0.5 F cm at a scan rate of 5 mV s. Replacing the aqueous electrolyte with a LiCl/PVA gel electrolyte can efficiently improve the cycling performance to 85% retention after 1600 cycles. The good electrochemical performance of the composites indicates their high potential as electrode materials for supercapacitors.
Porous
vanadium pentoxide (V2O5) microcrystals
with different morphologies were synthesized through the decomposition
of butterfly-like, rhombohedral, and flower-like ammonium metavanadate
(NH4VO3) microcrystals, which were synthesized
by the drowning-out crystallization of hydrothermal NH4VO3 aqueous solution using ethanol as both the antisolvent
and the template for the self-assembly of vanadate ions. The effects
of reaction conditions on the morphologies of products were characterized
by scanning electron microscopy (SEM), and the possible growth mechanism
was proposed. The electrochemical properties of the produced porous
V2O5 with different morphologies were studied
as battery-type electrodes for supercapacitors using 1 M LiClO4/propylene carbonate (PC) as the electrolyte. Rhombohedral
V2O5 exhibited the highest initial specific
capacitance of 641 F·g–1 at 0.5 A·g–1 among the three obtained morphologies, as well as
an excellent rate capability and cycling stability, with a retention
of over 119% after 2000 cycles, making it a promising electrode material
for supercapacitors. The influences of morphologies on the capacitance
and cycle performance are analyzed. The results indicate that the
increasing complexity of the structure leads to lower specific capacitance
because of the higher degree of electrode polarization and higher
resistance, while the structure stability of the microcrystals is
related to the rate capability as well as the cycling performance.
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