Redox-inactive metal single-site molecular complexes: a new generation of electrocatalysts for oxygen evolution?

Tímea Benkó; Dávid Lukács; Krisztina Frey; Miklós Németh; Márta M. Móricz; Dongyu Liu; Éva Kováts; Nóra V. May; Lionel Vayssieres; Mingtao Li; József S. Pap

doi:10.1039/D1CY01087E

Redox-inactive metal single-site molecular complexes: a new generation of electrocatalysts for oxygen evolution?†‡

Tímea Benkó,

^a Dávid Lukács,^a Krisztina Frey,^a Miklós Németh,^a Márta M. Móricz,^a Dongyu Liu,^b Éva Kováts,^c Nóra V. May,^d Lionel Vayssieres,

^b Mingtao Li

*^b and József S. Pap

*^a

Author affiliations

* Corresponding authors

^a Centre for Energy Research, Institute for Energy Security and Environmental Safety, Surface Chemistry and Catalysis Department, Konkoly-Thege street 29-33, 1121 Budapest, Hungary
E-mail: pap.jozsef@ek-cer.hu

^b International Research Center for Renewable Energy (IRCRE), State Key Laboratory of Multiphase Flow in Power Engineering (MFPE), Xi'an Jiaotong University, Xi'an, Shaanxi 710049, China
E-mail: mingtao@xjtu.edu.cn

^c Institute for Solid State Physics and Optics, Wigner Research Centre for Physics, P.O. Box 49, H-1525 Budapest, Hungary

^d Centre for Structural Science, Research Centre for Natural Sciences, Magyar tudósok körútja 2, Budapest, Hungary

Abstract

A molecular pre-catalyst complex, [Cu^II(indH)(OClO₃)(NCCH₃)](ClO₄)·CH₃CN (1·CH₃CN) with the 3N pincer ligand 1,3-bis(2′-pyridyl)iminoisoindoline (indH) was immobilized on indium tin oxide (ITO) transparent conducting substrate to generate O₂ electrocatalytically for over 20 hours at pH 10 in a carbonated buffer, reaching a turnover of 139 with no signs of CuO_x/Cu(OH)₂ formation at the surface. Further electrolysis experiments revealed that the catalyst was present in the aqueous phase, despite the poor initial solubility of the pre-catalyst (1). In order to identify the actual form responsible for this important catalytic reaction, the aquo complex [Cu^II(ind)(OClO₃)(OH₂)]·CH₃OH (2·CH₃OH) was structurally characterized. Spectroscopic investigations of a solid isolated from the buffer used in the electrolysis reaction and solution equilibrium studies using 2 indicated that the [Cu^II(ind)(OH)] form occurs at pH 10. Electron paramagnetic resonance (EPR) spectroscopy and DFT calculations confirmed a distorted {3N,O}_eq coordination plane in solution, as found in 2. The buffer (i.e. bicarbonate/carbonate) may affect reactivity in two ways: as an external base facilitating the proton-coupled electron transfer steps; and/or displacing the inner-sphere solvent molecules from the favourable quasi-equatorial position, thus inhibiting the catalysis. Structural features of a tri-nuclear cluster [Cu^II₃(ind)₃(μ₃-CO₃)(CH₃OH)(OClO₃)] (3) isolated under basic conditions confirmed that beside acting as an external base, the inhibiting effect of carbonate anions may also play a role. In acetonitrile-water solutions, where both 1 and 2 exhibit reasonable solubility, experimental findings supported by DFT calculations suggest that it is the ind⁻ ligand which is being oxidized while the cupric ion remains redox-inactive which is very unusual yet of great significance for the creation of a new generation of low-cost Cu-based water oxidation catalysts as well as potentially other 1st row transition metals.

Catalysis Science & Technology

Redox-inactive metal single-site molecular complexes: a new generation of electrocatalysts for oxygen evolution?†‡

Abstract

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