The development of earth-friendly
efficient electrocatalysts for
the oxygen evolution reaction (OER) becomes crucial for renewable
energy production. In this work, green synthesized reduced cobalt
ferrocyanide at different time intervals (RCFC-t)
was demonstrated as an effective and long-lasting electrocatalyst
for the OER process. The RCFC-10 loaded glassy carbon electrode runs
at an overpotential of 321 mV (1.55 V) at 10 mA cm–2, and a lower overpotential of 291 mV exhibited by the optimal RCFC-10/nickel
foam was almost comparable to the benchmark catalyst, such as IrO2. This newborn RCFC-10 shows excellent OER performance and
durability over 250 h with 4.1% potential loss in alkaline medium.
At 1.58 V, the solar-driven water electrolysis demonstration supports
the efficiency of a newborn electrocatalyst in solar-to-hydrogen conversion.
These research findings confirm that low-cost greener synthesized
RCFC-10/NF can be used for large-scale hydrogen generation.
The development of high-performance catalysts for oxygen-evolution reaction (OER) is paramount for cost-effective conversion of renewable electricity to fuels and chemicals.
We report a promising synthetic method
for the binder-free synthesis
of a low-cost and efficient solar-driven electrolyzer [Co(OH)2/NF] consisting of earth abundant cobalt metal which can be
employed for hydrogen (and oxygen) generation in 1 M KOH. The direct
growth of Co(OH)2 on nickel foam (NF) [Co(OH)2/NF)] makes this an effective bifunctional catalyst-electrode pair
for water splitting with high activity and excellent stability. The
Co(OH)2/NF electrode exhibits an overpotential of 182 mV
(112 mV dec–1) for hydrogen evolution reaction (HER)
and 281 mV (88 mV dec–1) for oxygen evolution reaction
(OER) to achieve a current density of 10 mA cm–2 (without iR correction). Co(OH)2/NF
displays long-term durability (150 h) with a low potential loss of
3.1 and 3.4% for HER and OER, respectively. The active bifunctional
Co(OH)2/NF-electrode pair assists in constructing a water
electrolyzer that affords 10 mA cm–2@1.66 V. Co(OH)2/NF//Co(OH)2/NF exhibits high stability (over 150
h) with 4.1% potential loss. The earth abundant nonprecious-metal-based
electrode [Co(OH)2/NF] and the solar cell structure afforded
continuous evolution of hydrogen and oxygen (@1.65 V), which can be
projected to allow for low-cost, large-scale hydrogen generation.
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