Hydrogen production through the reduction of water appears to be a convenient solution for the long-run storage of renewable energies. However, economically viable hydrogen production requests platinum-free catalysts, because this expensive and scarce (only 37 ppb in the Earth's crust) metal is not a sustainable resource [Gordon RB, Bertram M, Graedel TE (2006) Proc Natl Acad Sci USA 103:1209 -1214]. Here, we report on a new family of cobalt and nickel diimine-dioxime complexes as efficient and stable electrocatalysts for hydrogen evolution from acidic nonaqueous solutions with slightly lower overvoltages and much larger stabilities towards hydrolysis as compared to previously reported cobaloxime catalysts. A mechanistic study allowed us to determine that hydrogen evolution likely proceeds through a bimetallic homolytic pathway. The presence of a proton-exchanging site in the ligand, furthermore, provides an exquisite mechanism for tuning the electrocatalytic potential for hydrogen evolution of these compounds in response to variations of the acidity of the solution, a feature only reported for native hydrogenase enzymes so far.bio-inspired chemistry ͉ cobaloxime ͉ electrocatalysis ͉ hydrogen evolution reaction ͉ hydrogenase H ydrogen production, through the reduction of water, appears to be a solution to consider for the long-run storage of renewable energetic resources (1). The hydrogen evolution reaction (her) is apparently a very simple reaction but, as with most multielectronic processes, it is a slow process that should be catalyzed. Nickel-based electrodes can be used for that aim in strongly alkaline media, but this technology results in average energetic yields (Ϸ50-70%), suffers from corrosion issues, and can hardly be miniaturized due to the lack of polymer exchange membrane (PEM) material that is stable under these conditions. Actually, technological research now focuses on PEM electrolytic cells for which carbon-supported platinum nanoparticles are generally used as catalysts. This scarce and expensive noble metal is, however, not a renewable resource. Thus, progress to a mature hydrogen economy depends on breakthroughs in finding new catalytic materials based on earth-abundant elements (2). To that aim, the combination of a common electrode material with a coordination complex of a first-row transition metal, able to catalyze the reaction at a potential close to the standard potential of the H ϩ /H 2 couple, seems attractive. Macrocyclic cobalt complexes are very competitive in that respect (3). In the past four years, we and others reported on cobaloximes-cobalt complexes containing bridged bidentate oximato ligands (see Scheme 1)-(4-7) as a new class of such catalysts with good catalytic stability and Ϸ250-300 mV overvoltage-the difference between the observed catalytic potential and the thermodynamic H 2 /2H ϩ ϩ 2 e Ϫ equilibrium. To date, these catalysts are among the most efficient ones and, thus, are currently exploited for the construction of H 2 -evolving photocatalytic devices that actuall...
The viability of a hydrogen economy depends on the design of efficient catalytic systems based on earth-abundant elements. Innovative breakthroughs for hydrogen evolution based on molecular tetraimine cobalt compounds have appeared in the past decade. Here we show that such a diimine-dioxime cobalt catalyst can be grafted to the surface of a carbon nanotube electrode. The resulting electrocatalytic cathode material mediates H(2) generation (55,000 turnovers in seven hours) from fully aqueous solutions at low-to-medium overpotentials. This material is remarkably stable, which allows extensive cycling with preservation of the grafted molecular complex, as shown by electrochemical studies, X-ray photoelectron spectroscopy and scanning electron microscopy. This clearly indicates that grafting provides an increased stability to these cobalt catalysts, and suggests the possible application of these materials in the development of technological devices.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
hi@scite.ai
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.