A Cu–Co–P
electrocatalyst for hydrogen evolution
reaction (HER) was designed with a dendritic and porous foam structure.
Fabricated by one-step electrodeposition with binary alloy on a hydrogen
bubble template, the porous foam exhibited remarkable HER activity
in alkaline conditions. Cu was the dominant element in the core and
shell region and acted for 3D structure formation. Cu–Co formed
in the shell part and acted as an active region for hydrogen evolution
reaction. Also, as the amount of P increased in the Cu–Co–P
foams, the pore numbers, the electrochemical surface area (ECSA),
and the HER activity were enhanced. The improved activity is believed
to originate from the charge separation between the negatively charged
P (δ–) and positively charged Cu and Co (δ+), the larger ECSA, and increased porosity.
Uniquely
nanostructured CuCo2O4 is presented
as an electrocatalyst for oxygen evolution reactions (OER). CuCo2O4 particles in a chestnut-burr-like shape (CCO*,
where ∗ = chestnut burr) were hydrothermally synthesized around
fibers of Ni foam substrates as current collectors. Chestnut burrs
4 μm on average had thorns consisting of less than five threads.
Each thread was made of a consecutive array of nanobeads less than
10 nm. Nanovoids or nanopores were found between nanobeads. The chestnut-burr
structure of CCO* allowed IrO2-overwhelming OER activity.
By using the hierarchically nanostructured electrocatalyst directly
grown on current collectors without binders and conducting agents,
high performances of anion exchange membrane (AEM) electrolysis was
demonstrated. Three merits of the electrode architecture were emphasized.
First, mass transfer pathways for reactants and products were secured
in a microscale between thorns and in a nanoscale between nanobeads.
Second, more active sites were exposed to electrolytes in the hierarchical
structure. Third, direct growth of active materials on conductive
substrates improved adhesion and electrical conduction.
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