Developing cost-effective and efficient
hydrogen evolution reaction (HER) electrocatalysts for hydrogen production
is of paramount importance to attain a sustainable energy future.
Reported herein is a novel three-dimensional hierarchical architectured
electrocatalyst, consisting of platinum–copper–nickel
nanoparticles-decorated carbon nanofiber arrays, which are conformally
assembled on carbon felt fabrics (PtCuNi/CNF@CF) by an ambient-pressure
chemical vapor deposition coupled with a spontaneous galvanic replacement
reaction. The free-standing PtCuNi/CNF@CF monolith exhibits high porosities,
a well-defined geometry shape, outstanding electron conductivity,
and a unique characteristic of localizing platinum–copper–nickel
nanoparticles in the tips of carbon nanofibers. Such features render
PtCuNi/CNF@CF as an ideal binder-free HER electrode for hydrogen production.
Electrochemical measurements demonstrate that the PtCuNi/CNF@CF possesses
superior intrinsic activity as well as mass-specific activity in comparison
with the state-of-the-art Pt/C catalysts, both in acidic and alkaline
solutions. With well-tuned composition of active nanoparticles, Pt42Cu57Ni1/CNF@CF showed excellent durability.
The synthesis strategy reported in this work is likely to pave a new
route for fabricating free-standing hierarchical electrodes for electrochemical
devices.