Electrochemical Behavior of Pyridinium and <i>N</i>‐Methyl Pyridinium Cations in Aqueous Electrolytes for CO<sub>2</sub> Reduction

Lebègue, Estelle; Agullo, Julia; Bélanger, Daniel

doi:10.1002/cssc.201701745

Cited by 19 publications

(23 citation statements)

References 64 publications

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“…That pyridine is a catalyst for the electrochemical reduction CO 2 is controversial: First, most homogeneous catalysts do not catalyze electrochemical reduction of CO 2 beyond the two-electron level (thus carbon monoxide or formate are the normal reduction product(s)); second, pyridine is such a simple and readily accessible heterocycle. Third, several authors have found the experimental evidence suffers from a lack of reproducibility. − For noble metal electrodes, the consensus viewpoint has recently trended toward weak initial catalysis, followed by poisoning by produced carbon monoxide, which in sum leads to very poor turnovers. At semiconductor electrodes, photoelectrocatalysis of CO 2 reduction by pyridine is understood to be a heterogeneous process. ,, Other studies, however, do provide evidence that pyridine may be an important homogeneous catalyst, such as in the [Ru(bpy) 3 ] 2+ -photosensitized production of methanol from CO 2 in the presence of pyridine catalyst without the use of electrodes, albeit with low turnover numbers. − The ongoing debate certainly indicates that simple heterocycles may possess OHD functionality useful in the electrochemical, and/or chemical, reduction of carbon dioxide.…”

Section: Introductionmentioning

confidence: 99%

Evaluation of Organic Hydride Donors as Reagents for the Reduction of Carbon Dioxide and Metal-Bound Formates

et al. 2018

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A variety of organic hydride donors (OHDs) have been tested as reagents for the transfer of hydride to iron formato complexes in the activation and reduction of carbon dioxide. Theoretical calculations show that the selection of OHD and solvent is crucial when planning systems involving OHD cooperativity. Strong consideration is given to the likelihood that metal centers may deactivate formate to hydride attack, since, in general, the formate group has more resonance stabilization energy when complexed to a metal center compared to an organoformate or formic acid. It is experimentally demonstrated that 1,2dihydropyridine is not a competent reducing agent for carbon dioxide.

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Section: Introductionmentioning

confidence: 99%

Evaluation of Organic Hydride Donors as Reagents for the Reduction of Carbon Dioxide and Metal-Bound Formates

et al. 2018

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“…−0.35 V vs SHE for the experimental value. There is no way to check experimentally the computed value because no corresponding one-electron response couple is observable on an inert electrode such as glassy carbon . However, the difference between the value and the potential where the reaction take place is so large that there is little doubt that the reaction cannot involve the intermediacy of PyH • .…”

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confidence: 99%

Catalysis of CO₂ Electrochemical Reduction by Protonated Pyridine and Similar Molecules. Useful Lessons from a Methodological Misadventure

2018

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Electrochemical reduction of carbon dioxide is a particularly important issue in energy and environment contemporary challenges. It mobilized for several decades many researchers in the fields of catalysis by low-valent transition metal complexes. In this context, the report that a molecule as simple as protonated pyridine could catalyze the 6e − + 6H + conversion of CO 2 into methanol and triggered quite a lot of interest and amazement, even if the Faradaic yield was relatively modest (20%) and a precious metal (Pt) had to be used as an electrode material. Successive investigations of the same system or of systems involving molecules similar to protonated pyridine produced divergent results. The amount of data available at present from several research groups is sufficiently large to try to take stock of the situation. This concerns first and foremost a critical examination of the nature and Faradaic yields of electrolysis products. It also deals with the extensive use in this research of a nondestructive electrochemical techniquecyclic voltammetryas a footprint of the existence of the catalysis process and a way to access its mechanism. As shown here, serious methodological problems arise in this connection, whose discussion may serve as general guidelines for safer future use of cyclic voltammetry. The same type of methodological questions also result from the theoretical computations that have abundantly accompanied experimental reports.

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“…It should be noted, however, that not all ILs act as co-catalysts. Tetraalkylammonium and phosphonium salts were initially considered as co-catalysts but have since been questioned, and N -alkylpyridinium-based ILs do not function as co-catalysts. , Therefore, active non-functionalized ionic co-catalysts are currently limited to Im, pyrazolium, and pyrrolidinium ILs, each of which comprises a five-membered heterocycle.…”

Section: Introductionmentioning

confidence: 99%

Principal Descriptors of Ionic Liquid Co-catalysts for the Electrochemical Reduction of CO₂

Vasilyev

Shyshkanov

Shirzadi

et al. 2020

ACS Appl. Energy Mater.

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Electrochemical reduction of carbon dioxide (CO2RR) is promoted by ionic liquid (IL) co-catalysts, and several mechanisms have been proposed to explain their role. Due to the complexity of the CO2RR and the limited number of active IL co-catalysts, a consensus on the precise role of ILs has not been reached, and it is not possible to improve their activity in a rational way. Herein, we describe guanidinium (Gua) ILs that act as co-catalysts for the CO2RR when employed in non-aqueous electrolytes. The peripheral substituents of the Gua cation were systematically modified allowing the IL co-catalytic properties to be fine-tuned, and on the basis of the observed substitution effects, charge delocalization and availability were shown to be the critical descriptors determining co-catalytic activity. These descriptors can be used to rationalize activity trends for other classes of IL co-catalysts.

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Electrochemical Behavior of Pyridinium and N‐Methyl Pyridinium Cations in Aqueous Electrolytes for CO₂ Reduction

Cited by 19 publications

References 64 publications

Evaluation of Organic Hydride Donors as Reagents for the Reduction of Carbon Dioxide and Metal-Bound Formates

Evaluation of Organic Hydride Donors as Reagents for the Reduction of Carbon Dioxide and Metal-Bound Formates

Catalysis of CO₂ Electrochemical Reduction by Protonated Pyridine and Similar Molecules. Useful Lessons from a Methodological Misadventure

Principal Descriptors of Ionic Liquid Co-catalysts for the Electrochemical Reduction of CO₂

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Electrochemical Behavior of Pyridinium and N‐Methyl Pyridinium Cations in Aqueous Electrolytes for CO2 Reduction

Cited by 19 publications

References 64 publications

Evaluation of Organic Hydride Donors as Reagents for the Reduction of Carbon Dioxide and Metal-Bound Formates

Evaluation of Organic Hydride Donors as Reagents for the Reduction of Carbon Dioxide and Metal-Bound Formates

Catalysis of CO2 Electrochemical Reduction by Protonated Pyridine and Similar Molecules. Useful Lessons from a Methodological Misadventure

Principal Descriptors of Ionic Liquid Co-catalysts for the Electrochemical Reduction of CO2

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Electrochemical Behavior of Pyridinium and N‐Methyl Pyridinium Cations in Aqueous Electrolytes for CO₂ Reduction

Catalysis of CO₂ Electrochemical Reduction by Protonated Pyridine and Similar Molecules. Useful Lessons from a Methodological Misadventure

Principal Descriptors of Ionic Liquid Co-catalysts for the Electrochemical Reduction of CO₂