posted on 2022-01-11, 22:29authored byYuling Zhuo, Eric Prestat, Ian A. Kinloch, Mark A. Bissett
Two-dimensional
(2D) materials such as graphene and molybdenum
disulfide (MoS2) have been investigated widely for applications
in energy storage, including supercapacitors, due to their high specific
surface area, potential redox activity, and mechanical flexibility.
However, electrodes comprising either pure graphene and MoS2 have failed to reach their potential due to restacking of the layered
structure and poor electrical conductivity. It has been shown previously
that composite electrodes made from a mixture of graphene and MoS2 partially counteract these issues; however, performance is
still limited by poor mixing at the nanoscale. Herein, we form a true
composite electrode by chemically functionalizing the graphene so
that the negatively charged surface can self-assemble with the positively
charged 1T-MoS2 to give an alternating layer structure.
These alternately restacked 2D materials were then used to produce
supercapacitor electrodes, and their energy storage properties were
characterized. This stacked structure has increased the interlayer
spacing of 1T-MoS2 which was indicated by the increase
in the intensity of the (001) peak in the X-ray diffraction spectra.
Furthermore, the typically metastable 1T-MoS2 was stabilized
by the interaction with the functionalized graphene, preventing it
reverting back to the 2H phase, which was observed when pristine graphene
was used. The graphene was functionalized using either 4-bromobenzenediazonium
or 4-nitrobenzenediazonium, with the latter giving optimal capacitance
when mixed with the MoS2. The alternative layer graphene–MoS2 structure was confirmed by Raman spectroscopy and electron
microscopy, leading to a high specific capacitance (290 F cm–3 at 0.5 A g–1) and 90% retention of capacitance
after 10 000 cycles.