Transition metal silicates are a potential supercapacitor
electrode
material due to appreciable theoretical specific capacitance and high
energy density. However, the inherent narrow voltage window range
and poor conductivity lead to unsatisfactory electrochemical properties.
Herein, the carbon composited iron cobalt silicate (denoted as CHOAMFC)
with a two-dimensional lamellar structure is designed to enhance the
electrical conductivity, where two-dimensional mesoporous silica obtained
from montmorillonite was used as the silicon source and template to
combine with Fe2+ and Co2+. The CHOAMFC exhibits
a specific capacitance of 1008.3 F·g–1 at 0.5
A·g–1 with a long lifespan of 107% after 10 000
cycles. Meanwhile, the assembled hybrid supercapacitor device (CHOAMFC//AC)
displays the energy density of 50.9 W h·kg–1 at 275 W·kg–1 as well as excellent cycling
stability after 7000 cycles. The great supercapacitor performance
is attributed to the uniformly distributed secondary nanosheets on
the lamellar substrate that enhance the exposure of sites and the
contact with the electrolyte, allowing for easier ion transport. This
study explores a strategy of CHOAMFC based on the resource endowment
and crystal structure of natural minerals, which provides a feasible
idea to obtain two-dimensional layered bimetallic silicate supercapacitor
electrode materials with excellent electrochemical performance.
Mo2C is a promising electrocatalyst for hydrogen evolution reaction (HER) on account of its Pt-like electronic features. However, the electronic structure of pure Mo2C is unfavourable for the desorption of...
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