posted on 2020-08-04, 20:41authored byLin Ye, Yunqiu Du, Yuguang Zhao, Lijun Zhao
For
achieving long duration and high efficiency of hydrogen evolution
reaction (HER) catalysts, the key mainly lies in constructing porous
structures, improving conductivity, and tailoring chemical components.
Inspired by this, we in situ deposited W-doped Ni3S2 nanoparticles modified with NiFeLa hydroxide
on Ni foam (NF). Our work primarily concentrates on optimizing the
dosage of W element and constructing open nanostructures with rich
active sites. The internal W-doped Ni3S2 nanoparticles
enable high conductivity, and the outer NiFeLa hydroxide nanosheets
form more active sites, which help to monitor the electronic structure
and generate synergistic effects. Both optimization of tungsten hexachloride
dosage and epitaxial growth of NiFeLaOH nanosheets greatly ameliorate
the surface active area, conductivity, and electronic structure of
the hybrid nanomaterial. When directly applied to alkaline HER catalytic
systems, the resulting catalyst presents favorable electrochemical
performance, such as low HER overpotentials (67 mV at 10 mA cm–2 and 330 mV at 552 mA cm–2). Remarkably,
after a duration of 40 h, the catalytic activity presents pretty slight
attenuation (amplification of ∼15 mV for overpotential), which
indicates its ultralong stability. This research introduces an effective
method to tune electrocatalytic performance by doping W element into
Ni3S2 and coupling with NiFeLa hydroxide.