We
report a simple, facile, and safe route for preparation of cobalt–cobalt
phosphide (Co/Co2P) nanoparticles and demonstrate their
application as efficient low-cost catalysts for electrochemical water
splitting. The catalyst achieves good performance in catalyzing both
the cathode and anode half-cell water-splitting reactions in 1.0 M
KOH and the hydrogen evolution reaction in an acidic electrolyte,
0.5 M H2SO4. For the oxygen evolution reaction
in 1.0 M KOH, a current of 10 mA cm–2 was
attained at 0.39 V overpotential on a glassy carbon electrode, while
an overpotential of 0.19 V was attained at 50 mA cm–2 when the catalyst was supported on nickel foam.
The modification of nickel with boron or phosphorus leads to significant enhancement of its electrocatalytic activity for the oxygen evolution reaction (OER). However, the precise role of the guest elements, B and P, in enhancing the OER of the host element (Ni) remains unclear. Herein, we present insight into the role of B and P in enhancing electrocatalysis of oxygen evolution by nickel borides and nickel phosphides. The apparent activation energy, Ea*, of electrocatalytic oxygen evolution on Ni2P was 78.4 kJ/mol, on Ni2B 65.4 kJ/mol, and on Ni nanoparticles 94.0 kJ/mol, thus revealing that both B and P affect the intrinsic activity of nickel. XPS data revealed shifts of −0.30 and 0.40 eV in the binding energy of the Ni 2p3/2 peak of Ni2B and Ni2P, respectively, with respect to that of pure Ni at 852.60 eV, thus indicating that B and P induce opposite electronic effects on the surface electronic structure of Ni. The origin of enhanced activity for oxygen evolution cannot, therefore, be attributed to such electronic modification or ligand effect. Severe changes induced on the nickel lattice, specifically, the Ni‐Ni atomic order and interatomic distances (strain effect), by the presence of the guest atoms seem to be the dominant factors responsible for enhanced activity of oxygen evolution in nickel borides and nickel phosphides.
We report herein a new simplified approach to metal-free N-doped carbon aerogels made from ionic liquids by a bottom-up "salt templating" strategy, which are known to be promising electrocatalytic materials. An optimized pore transport system as well as a high catalytically active surface allowed the ionic liquid-derived carbons to
An excellent electrocatalyst for reversible oxygen reduction and oxygen evolution synthesized by direct growth of nitrogen-doped carbon nanotubes on cobalt boride nanoparticles.
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