A combination of the exceptional stability of fac-[Ir(H2O)3(NO2)3] together
with thermolability of nitro and aqua ligands and high solubility
in various solvents makes it promising as a brand-new chlorine-free
precursor of iridium for the preparation of heterogeneous catalysts.
In the current work, a new technique of fac-[Ir(H2O)3(NO2)3] preparation based
on hydrothermal treatment of (NH4)3[Ir(NO2)6] was developed. For this purpose, the influence
of reaction parameters such as the reaction time, temperature, and
pH of the solution on the process of hexanitroiridate salt hydrolysis
was investigated. The synthesized fac-[Ir(H2O)3(NO2)3] solution in this optimized
way was used for the preparation of the series of Ir/g-C3N4 catalysts, which were evaluated in the water oxidation
reaction with NaIO4 utilized as a sacrificial reagent.
A 20-fold enhancement of the oxygen evolution reaction (OER) activity
was found to take place under visible light (λ = 411 nm) illumination
of the systems. The highest rate of the photoinduced OER per iridium
center was achieved by the Ir0.005/g-C3N4 (air, 400°C) catalyst with an exceptional turnover frequency
value of 967 min–1 approaching the activity of known
homogeneous iridium OER catalysts. The leaching experiments have shown
that aquated Ir species are generated in a solution after prolonged
functioning of the catalysts. Despite this, in the closed system the
photodriven OER activity persists at a steady-state level evidencing
an equilibrium achieved between dissolved and anchored Ir species
forming catalytic tandem with the g-C3N4.
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