Abstract
The water oxidation half-reaction is considered the bottleneck in the development of technological advances to replace fossil fuels with sustainable and economically affordable energy sources. In natural photosynthesis, water oxidation occurs in the oxygen evolving complex (OEC), a manganese-oxo cluster {Mn4CaO5} with a cubane-like topology that is embedded within a redox-active protein environment located in photosystem II (PS II). Therefore, the preparation of biomimetic manganese-based compounds is appealing for the development of efficient and inexpensive water oxidation catalysts. Here, we present the water oxidation catalytic activity of a high-nuclearity mixed-metal manganese-strontium cluster, [MnIII12MnII6Sr(μ4-O8)(μ3-Cl)8(HLMe)12(MeCN)6]Cl2∙15MeOH (Mn18Sr) (HLMe = 2,6-bis(hydroxymethyl)-p-cresol), in neutral media. This biomimetic mixed-valence cluster features different cubane-like motifs and it is stabilized by redox-active, quinone-like organic ligands. The complex displays a low onset overpotential of 192 mV and overpotentials of 284 and 550 mV at current densities of 1 mA cm−2 and 10 mA cm−2, respectively. Direct O2 evolution measurements under visible light-driven water oxidation conditions demonstrate the catalytic capabilities of this cluster, which exhibits a turnover frequency of 0.48 s−1 and a turnover number of 21.6. This result allows for a direct comparison to be made with the structurally analogous Mn-oxo cluster [MnIII12MnII7(µ4-O)8(µ3-OCH3)2(µ3-Br)6(HLMe)12(MeOH)5(MeCN)]Br2·9MeCN·MeOH (Mn19), the water oxidation catalytic activity of which was recently reported by us. This work highlights the potential of this series of compounds towards the water oxidation reaction and their amenability to induce structural changes that modify their reactivity.
Highlights
Water oxidation catalysis has become a central focus area in the quest for replacing fossil fuel combustion for energy production by renewable and environmentally friendly energy sources [1,2]
Mn18 Sr-modified carbon paste (CP) working electrodes, where the Mn18 Sr weight ratio in the CP blend was kept at 30% (Mn18 Sr/CP)
Is worth mentioning that a crossover loop process appears at the firsts cyclic voltammetry (CV) cycles
Summary
Water oxidation catalysis has become a central focus area in the quest for replacing fossil fuel combustion for energy production by renewable and environmentally friendly energy sources [1,2]. Water represents the ideal source of reducing equivalents to produce H2 via the water splitting reaction, conceptually mimicking natural photosynthesis This process provides the storage of clean energy in the form of chemical bonds with an intrinsic high gravimetric energy density [3,4,5]. The water oxidation half-reaction (Equation (1)) within this scheme is complex and highly energetically demanding. It requires the use of water oxidation catalysts (WOCs) that alleviate the energy requirements associated with each of the steps in the reaction mechanism and accelerate the sluggish kinetics of the O−O bond formation [6,7,8]. The lack of cost-effective WOCs hampers the generation of economically affordable
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