The Co–Ni–B@Ni foam catalyst prepared by a simple electroless plating method exhibits high and stable electrocatalytic activity towards the water splitting.
Platinum
(Pt) is well-known as the best-performing catalyst for
the hydrogen evolution reaction (HER), but its practical application
is severely hindered by its prohibitively high cost and problematic
performance in alkaline electrolyte. Herein, we report that the issues
of intrinsic activity and cost concern of Pt can be simultaneously
addressed by employing a combination of concerted catalysis and nanoengineering
strategies. Motivated by our density functional theory (DFT) calculations
that the cooperative catalysis between Pt and NiO would lead to a
better HER activity in comparison to Pt solely in alkaline solution,
we successfully synthesized a Pt/NiO@Ni/NF nanocomposite catalyst
by depositing highly dispersed Pt nanoclusters/nanoparticles on a
honeycomb-like NiO@Ni film supported on Ni foam (NF). The resulting
Pt/NiO@Ni/NF catalyst outperforms the commercial Pt/C catalyst with
a high and stable HER activity in alkaline solution and, more impressively,
with an economical Pt content as low as ∼0.1 mg cm–2.
The design and synthesis of high-performance hydrogen evolution reaction (HER) catalysts requires an overall consideration of intrinsic activity and number of active sites as well as electric conductivity. We herein report a facile synthesis of a cost-effective catalyst that can simultaneously address these key issues. A cobalt molybdenum oxide hydrate (CoMoO 4 •nH 2 O) with a 3D hierarchical nanostructure can be readily grown on nickel foam using a hydrothermal method. Calcination treatment of this precursor material under a reductive atmosphere resulted in the formation of Co nanoparticles on the Co 2 Mo 3 O 8 surface, which worked in concert to act as active sites for the HER. In addition, the resulting Co 2 Mo 3 O 8 from the dehydration and reduction reactions of CoMoO 4 •nH 2 O showed remarkable increases in both active surface area and electrical conductivity. As a consequence of these favorable attributes, the catalyst exhibited electrocatalytic performance comparable to that of the commercial Pt/C catalyst for the HER in alkaline solution, which is promising for practical water-splitting applications.
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