4.7 Article

Mechanistic insights into the electrochemical reduction of CO2 to CO on Ni(salphen) complexes

Journal

INORGANIC CHEMISTRY FRONTIERS
Volume 10, Issue 14, Pages 4175-4189

Publisher

ROYAL SOC CHEMISTRY
DOI: 10.1039/d3qi00424d

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Cyclic voltammetry and bulk electrolysis experiments showed that [Ni(ii)(salphen)] [1], [Ni(ii)(Bu-t-salphen)] [2], and a binuclear Ni(ii) compound combining salphen and Bu-t-salphen [3] can react with CO2 to generate a stable metal-carbonyl species under anaerobic conditions. When exposed to air, a stoichiometric amount of CO is released and protonation regenerates the initial complex. Through various spectroscopy studies and DFT calculations, it is proposed that the reduction of [Ni(i)(salphen)](-), (2)[1](-), leads to the formation of a CO2 complex, (2)[1(CO2)](-), which is further reduced to (3)[1(CO2)](2-). After protonation, the coordinated CO2 is reduced to CO and released, regenerating (1)[1]. The release of CO competes with CO2 in the second cycle, deactivating the system.
Cyclic voltammetry and bulk electrolysis showed that [Ni(ii)(salphen)] [1], [Ni(ii)(Bu-t-salphen)] [2], and a binuclear Ni(ii) compound combining salphen and Bu-t-salphen [3] react with CO2 to yield a metal-carbonyl species that is stable under an oxygen free atmosphere. Upon exposure to air, a stoichiometric amount of CO is released (detected by gas chromatography) and protonation regenerates the initial complex. To shed light on the mechanism of CO2 reduction and O-2-dependent CO release by [1], UV-vis, EPR and SEC-IR spectroscopy studies complemented with DFT calculations were performed. It is proposed that the mono reduced [Ni(i)(salphen)](-), (2)[1](-), formed a CO2 complex, (2)[1(CO2)](-), which was then further reduced to (3)[1(CO2)](2-). After addition of two protons, the coordinated CO2 was reduced to CO and released, regenerating (1)[1]. Alternatively, (2)[1(CO2)](-) is protonated and then reduced to the same intermediate as before, continuing the same way. In the second cycle, the CO released competed with CO2 and coordinated to (2)[1](-) much more strongly, thereby deactivating the system. The new (2)[1(CO)](-) was reduced to (3)[1(CO)](2-) which was identified by comparison of experimental spectroscopic (UV-vis, EPR, SEC-IR) data with DFT calculated parameters.

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