Efficient and selective molecular catalyst for the CO
            <sub>2</sub>
            -to-CO electrochemical conversion in water

Costentin, Cyrille; Robert, Marc; Savéant, Jean‐Michel; Tatin, Arnaud

doi:10.1073/pnas.1507063112

Cited by 294 publications

(304 citation statements)

References 38 publications

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“…Furthermore, suitable functional groups can be introduced to the porphyrin rings to adjust the redox potential and pKa. [73] It is important to note that Shen et al also found the production of small amounts of CH 4 and CH 3 OH originating from CO further reduction [69] and they claimed that the CO further reduction conformed to coupled proton-electron transfer. [72] …”

Section: Decoupling Of Proton and Electron Transfermentioning

confidence: 98%

Recent Advances in Breaking Scaling Relations for Effective Electrochemical Conversion of CO₂

Sun

2016

Advanced Energy Materials

338

277

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and selectively produce carbon-containing products from CO 2 with reasonably low overpotentials and low cost.From the theoretical point of view, electrochemical CO 2 reduction, similar to many other electrochemical energy conversion processes on metal surfaces, comprise of multiple concerted or sequential proton-electron transfer reactions. In 2004, Nørskov et al. [2] developed a concise and effective scheme to understand the origin of the overpotential, which was denoted as the computational hydrogen electrode (CHE) model. They claimed that due to the relative low proton transfer barriers, the kinetic aspects in the proton transfer was omitted, and the rate-determining step was the one with the most positive free energy change ΔE max . To make the free energy of the rate-determining step become zero, a limiting potentialneeds to be applied. If we denote the equilibrium potential of a given electrochemical reaction as U eq , the overpotential wouldThe overpotential thereby originates from the relative stability between certain adsorbed intermediates. For example, the overpotential for 4-electron oxygen reduction reaction (ORR) is ascribed to the high adsorption free energy barrier of *OOH on the weak binding materials or the high desorption free energy barrier of *OH on the strong binding materials. [3] Similarly, when excluding the Tafel mechanism, the overpotential for hydrogen evolution reaction (HER) originates from either the high adsorption free energy barrier of *H (Volmer step) or the high desorption barrier of the same intermediate (Heyrovsky step). [4] Based on the Sabatier principle, [5] when the maximum electrocatalytic activity is reached in these reactions, the binding of the reaction intermediates should be neither too strong nor too weak. In HER, where only *H is emerged as the reaction intermediate, it is easier to achieve a maximum reactivity with negligible overpotential because the binding energy of *H is not limited and can be tuned freely. If the binding energy of *H on a certain material renders the adsorption free energy of *H close to zero, the overpotential will be negligible. Such an electroactive electrode for HER indeed exists, say the platinum electrode. However, for electrocatalytic reactions with multiple proton-electron transfer steps, the case is much more complex. The overpotential cannot be lowered to a negligible value because the relative The increasing concentration of CO 2 in the atmosphere, and the resulting environmental problems, call for effective ways to convert CO 2 into valuable fuels and chemicals for a sustainable carbon cycle. In such a context, CO 2 electrocatalytic reduction has been hotly studied due to the merits of ambient operational conditions and easy control of the reaction process by changing the applied potential. Among the various systems studied, Cu and Au are found to possess the highest Faradaic efficiency toward cathodic electrocatalytic conversion of CO 2 to hydrocarbons and CO, respectively. However, both of them suffer from large overpotentials ...

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Section: Decoupling Of Proton and Electron Transfermentioning

confidence: 98%

Recent Advances in Breaking Scaling Relations for Effective Electrochemical Conversion of CO₂

Sun

2016

Advanced Energy Materials

338

277

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“…[4,5] These catalysts are mainly active in aprotic solvent with reaction products being mostly CO and more rarely HCOOH. [9,10] In that case,C O production was achieved with over 90 %selectivity at neutral pH and am oderate 450 mV overpotential. Ni cyclam was first reported as as elective and efficient catalyst of the CO 2 -to-CO conversion in water at am ercury surface electrode,with favorable specific interactions of the catalytic adsorbed species with the surface, [6,7] while the use of acarbon electrode leads to much less efficiencyi nt erms of rate (maximal turnover frequency of 90 s À1 )a nd turnover (4 cycles).…”

mentioning

confidence: 93%

A Hybrid Co Quaterpyridine Complex/Carbon Nanotube Catalytic Material for CO₂ Reduction in Water

et al. 2018

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Associating a metal-based catalyst to a carbon-based nanomaterial is a promising approach for the production of solar fuels from CO . Upon appending a Co quaterpyridine complex [Co(qpy)] at the surface of multi-walled carbon nanotubes, CO conversion into CO was realized in water at pH 7.3 with 100 % catalytic selectivity and 100 % Faradaic efficiency, at low catalyst loading and reduced overpotential. A current density of 0.94 mA cm was reached at -0.35 V vs. RHE (240 mV overpotential), and 9.3 mA cm could be sustained for hours at only 340 mV overpotential with excellent catalyst stability (89 095 catalytic cycles in 4.5 h), while 19.9 mA cm was met at 440 mV overpotential. Such a hybrid material combines the high selectivity of a homogeneous molecular catalyst to the robustness of a heterogeneous material. Catalytic performances compare well with those of noble-metal-based nano-electrocatalysts and atomically dispersed metal atoms in carbon matrices.

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“…Hence, CO 2 reduction/activation by 3 d metal‐based catalysts has received intense interest. Among noteworthy examples of homogeneous catalysts are Fe‐tetraphenylporphyrin and derivatives by Savéant and co‐workers, selective reduction of CO 2 to formate using [Fe 4 N(CO) 12 ] – by Berben and co‐workers, and reduction of CO 2 to methanol by borane with Ni and Fe pincer complexes by Guan and co‐workers . Li and co‐workers reported photo‐reduction of CO 2 to CO catalyzed by molecular Co complexes immobilized on solid support .…”

Section: Introductionmentioning

confidence: 99%

Ni^II Complexes of C‐Substituted Cyclam as Efficient Catalysts for Reduction of CO₂ to CO

2018

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Two new nickel(II) complexes of cyclams bearing C‐alkyl groups, Ni(MEC)OTf2 (1, MEC = 5,12‐diethyl‐7,14‐dimethyl‐1,4,8,11‐tetraazacyclotetradecane) and Ni(CTMC)OTf2 (2, CTMC = 5,7,12,14‐tetramethyl‐1,4,8,11‐tetraazacyclotetradecane), were prepared, and their similarity to NiII(MPC) (MPC = 5,12‐dimethyl‐7,14‐diphenyl‐1,4,8,11‐tetraazacyclotetradecane) in ring conformation was revealed through single‐crystal X‐ray diffraction studies. Solution electronic absorption spectroscopy indicates the retention of octahedral coordination mode for both 1 and 2 in 20 % aqueous acetonitrile. Cyclic voltammetry studies of 1 and 2 under CO2 in 20 % aqueous acetonitrile revealed significantly increased catalytic currents compared to previously studied NiII(cyclam) and NiII(MPC). Controlled potential electrolysis studies of 2 revealed a 250 % increase in CO turn over frequency from that of Ni(cyclam)OTf2 and a 40 % increase from that of Ni(MPC)OTf2. Such improvements establish the benefit of electronically donating substituents that minimize steric interference around the axial catalytic sites.

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Efficient and selective molecular catalyst for the CO ₂ -to-CO electrochemical conversion in water

Cited by 294 publications

References 38 publications

Recent Advances in Breaking Scaling Relations for Effective Electrochemical Conversion of CO₂

Recent Advances in Breaking Scaling Relations for Effective Electrochemical Conversion of CO₂

A Hybrid Co Quaterpyridine Complex/Carbon Nanotube Catalytic Material for CO₂ Reduction in Water

Ni^II Complexes of C‐Substituted Cyclam as Efficient Catalysts for Reduction of CO₂ to CO

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Efficient and selective molecular catalyst for the CO 2 -to-CO electrochemical conversion in water

Cited by 294 publications

References 38 publications

Recent Advances in Breaking Scaling Relations for Effective Electrochemical Conversion of CO2

Recent Advances in Breaking Scaling Relations for Effective Electrochemical Conversion of CO2

A Hybrid Co Quaterpyridine Complex/Carbon Nanotube Catalytic Material for CO2 Reduction in Water

NiII Complexes of C‐Substituted Cyclam as Efficient Catalysts for Reduction of CO2 to CO

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Efficient and selective molecular catalyst for the CO ₂ -to-CO electrochemical conversion in water

Recent Advances in Breaking Scaling Relations for Effective Electrochemical Conversion of CO₂

Recent Advances in Breaking Scaling Relations for Effective Electrochemical Conversion of CO₂

A Hybrid Co Quaterpyridine Complex/Carbon Nanotube Catalytic Material for CO₂ Reduction in Water

Ni^II Complexes of C‐Substituted Cyclam as Efficient Catalysts for Reduction of CO₂ to CO