Demands
for safer, faster, and more efficient energy storage systems have
motivated researchers to design and develop new electrode materials.
Ternary transition metal oxides are the electrode materials commonly
investigated for application in energy storage systems. Nevertheless,
the low active surface area and poor conductivity limit their electrochemical
performances. In the present study, nanoporous CuCo2S4 microspheres (CCS) electrode has been successfully prepared
via a facile self-template method for high-performance hybrid energy
storage devices. An ultrahigh specific capacitance of 1566 F g–1 at 2 A g–1 and a superb cycling
performance of 95.7% retention after 5000 GCD cycles have been obtained
for this electrode. In addition, when this CCS electrode is assembled
with an activated carbon (AC) electrode, the as-fabricated asymmetric
supercapacitor delivers outstanding performance with maximum power
and energy densities of 16 and 43.65 W h kg–1, respectively,
which is superior to conventional supercapacitors. The fabricated
supercapacitor can light two green LEDs for more than 15 min. This
work sheds a further light on the design of efficient electrodes which
can be utilized in the next generation of high-performance hybrid
energy storage devices.
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