The key to improve the performance of electrochemically
water splitting
and simplify the entire system is to develop a dual-functional catalyst,
which can be applied to catalyze the process of HER and OER. Therefore,
we synthesized a novel hollow CoO/Co4S3@CoO/Co4S3 heterojunction with a core–shell structure
as an excellent dual-functional catalyst. This sample is composed
of an outer hollow CoO/Co4S3 cubic thin shell
and an inner hollow CoO/Co4S3 sphere, and it
can provide abundant catalytic active sites while effectively promoting
the flow of reactants, products, and electrolytes. Meanwhile, the
O–Co–S bond in the heterojunction interface can promote
both the CoO active site in OER and theCo4S3 active site in HER. Therefore, the overpotential of the hollow CoO/Co4S3@CoO/Co4S3 is only 190
mV (OER) and 81 mV (HER), respectively, at the current density of
10 mA cm–2. Moreover, the hollow CoO/Co4S3@CoO/Co4S3 showed the outstanding
electrochemical stability in 60 h. In addition, in the two-electrode
system assembled from the hollow CoO/Co4S3@CoO/Co4S3, only the potential of 1.48 V can achieve the
current density of 10 mA cm–2. Impressively, the
commercial solar panel is sufficient to drive the two-electrode electrolyzer
consisting of hollow CoO/Co4S3@CoO/Co4S3. This finding offers a promising nonprecious metal-based
catalyst that can be applied to catalyze the electrochemical overall
water splitting.