Efficient Electrocatalytic CO<sub>2</sub>Reduction Driven by Ionic Liquid Buffer‐Like Solutions

Gonçalves, Wellington D. G.; Zanatta, Marcileia; Simon, Nathália Marcolin; Rutzen, Luciane M.; Walsh, Darren A.; Dupont, Jaı̈rton

doi:10.1002/cssc.201901076

Cited by 22 publications

(15 citation statements)

References 43 publications

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“… 62 Au 0.1 mol dm −3 [Bmim]OAc l /dimethyl sulfoxide/0.2 vol % H 2 O −1.80 V versus Ag/AgCl 8.6 CO 98 Gonçalves et al. 63 Pt 50 mM H[NTF 2 ] m /[Emim]NTF 2 – – HCOO − – Martindale et al. 51 Post-transition Metal Catalysts Bi 20 mM [Emim]BF 4 /acetonitrile/0.1 M TBAPF 6 −1.95 V versus SCE n 5.51 ± 1.2 CO 95 ± 6 DiMeglio et al.…”

Section: Main Textmentioning

confidence: 99%

Electroreduction of CO2 in Ionic Liquid-Based Electrolytes

2020

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Electroreduction of carbon dioxide (CO 2 ) to value-added chemicals and fuels is a promising approach for sustainable energy conversion and storage. Many electrocatalysts have been designed for this purpose and studied extensively. The role of the electrolyte is particularly interesting and is pivotal for designing electrochemical devices by taking advantage of the synergy between electrolyte and catalyst. Recently, ionic liquids as electrolytes have received much attention due to their high CO 2 adsorption capacity, high selectivity, and low energy consumption. In this review, we present a comprehensive overview of the recent progress in CO 2 electroreduction in ionic liquid-based electrolytes, especially in the performance of different catalysts, the electrolyte effect, as well as mechanism studies to understand the reaction pathway. Perspectives on this interesting area are also discussed for the construction of novel electrochemical systems.

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Section: Main Textmentioning

confidence: 99%

Electroreduction of CO2 in Ionic Liquid-Based Electrolytes

2020

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“…[38] The activation of CO 2 in these cases is probably caused by the breaking of the CO 2 linearity geometry, and in electroreductions, it is also assumed to be attributable to the stabilization of the CO 2 radical anion (CO 2 C À ) provided by the cation (usually imidazolium). [15,29,39] In some cases, the formation of bicarbonate/carbonate has been claimed as a result of the interaction of wet ILs containing phosphonium and ammonium cations associated with basic anions such as carboxylates or amino acids. [40,41] However, in most of these cases, it is claimed that basic (and even super-basic) anions perform a nucleophilic attack on CO 2 .…”

Section: Co 2 In Basic Ilsmentioning

confidence: 99%

“…Moreover, in various cases, the interaction of the IL pair changes the reactivity of the trapped water, which can easily react with substrates, products, and even with the IL. [8,9,19,[27][28][29][30] In this contribution, the different modes of interaction of CO 2 with bare ILs containing both nonbasic and mainly basic anions will be presented and discussed critically, considering recent examples reported in the literature. Finally, it will be demonstrated that simple concepts of acid-base chemistry can be used to explain and to design new ionic fluids for CO capture and activation.…”

Section: Introductionmentioning

confidence: 99%

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The Nature of Carbon Dioxide in Bare Ionic Liquids

2020

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“…This approach was leveraged by Rosen et al, who used a room-temperature ionic liquid (RTIL) promoter for CO 2 reduction at silver cathodes. Since then, several other researchers have studied the use of RTILs to promote the reduction of coordinated nitrosyls or CO 2 . − In particular, the efficient catalysis of CO 2 to CO was reported using a bismuth film electrode and ionic liquids, ,, and similar catalysis was carried out in acetonitrile/imidazolium-based electrolyte mixtures using thin CuSn films . In addition to promoting the reduction of small molecules, RTILs can also be used to direct the dominant reaction pathway for certain molecule activation processes. , While ionic interactions can accelerate the catalytic pathways, the use of protic ionic liquids (PIL) allows the promoter to facilitate both charge neutralization and provide the protons needed for a PCET reaction.…”

Section: Introductionmentioning

confidence: 99%

Reversible Proton-Coupled Reduction of an Iron Nitrosyl Porphyrin within [DBU–H]⁺-Based Protic Ionic Liquid Nanodomains

2021

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The reduction of [Fe(OEP)(NO)] has been studied in the presence of aprotic room-temperature ionic liquids (RTIL) and protic (PIL) ionic liquids dissolved within a molecular solvent (MS). The cyclic voltammetric results showed the formation of RTIL nanodomains at low concentrations of the RTIL/PIL solutions. The pK a values of the two PILs studied (i.e., trialkylammonium and [DBU−H] + -based ionic liquids) differed by four units in THF. While voltammetry in solutions containing all three RTILs showed similar potential shifts of the first reduction of [Fe(OEP)(NO)] to [Fe(OEP)(NO)] − at low concentrations, significant differences were observed at higher concentrations for the ammonium PIL. The trialkylammonium cation had previously been shown to protonate the {FeNO} 8 species at room temperature. Visible and infrared spectroelectrochemistry revealed that the [DBU−H] + -based PIL formed hydrogen bonds with [Fe(OEP)(NO)] − rather than formally protonating it. Despite these differences, both PILs were able to efficiently reduce the nitrosyl species to the hydroxylamine complex, which could be further reduced to ammonia. On the voltammetric time scale and when the switching potential was positive of the Fe(II)/Fe(I) potential, the hydroxylamine complex was re-oxidized back to the NO complex via direct oxidation of the coordinated hydroxylamine at low scan rates or initial oxidation of the ferrous porphyrin at high scan rates. The results of this work show that, while [DBU−H] + does not protonate electrochemically generated [Fe(OEP)(NO)] − , it still plays an important role in efficiently reducing the nitroxyl ligand via a series of proton-coupled electron transfer steps to generate hydroxylamine and eventually ammonia. The overall reaction rates were independent of the PIL concentration, consistent with the nanodomain formation being important to the reduction process.

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Efficient Electrocatalytic CO₂Reduction Driven by Ionic Liquid Buffer‐Like Solutions

Cited by 22 publications

References 43 publications

Electroreduction of CO2 in Ionic Liquid-Based Electrolytes

Electroreduction of CO2 in Ionic Liquid-Based Electrolytes

The Nature of Carbon Dioxide in Bare Ionic Liquids

Reversible Proton-Coupled Reduction of an Iron Nitrosyl Porphyrin within [DBU–H]⁺-Based Protic Ionic Liquid Nanodomains

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Efficient Electrocatalytic CO2Reduction Driven by Ionic Liquid Buffer‐Like Solutions

Cited by 22 publications

References 43 publications

Electroreduction of CO2 in Ionic Liquid-Based Electrolytes

Electroreduction of CO2 in Ionic Liquid-Based Electrolytes

The Nature of Carbon Dioxide in Bare Ionic Liquids

Reversible Proton-Coupled Reduction of an Iron Nitrosyl Porphyrin within [DBU–H]+-Based Protic Ionic Liquid Nanodomains

Contact Info

Product

Resources

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Efficient Electrocatalytic CO₂Reduction Driven by Ionic Liquid Buffer‐Like Solutions

Reversible Proton-Coupled Reduction of an Iron Nitrosyl Porphyrin within [DBU–H]⁺-Based Protic Ionic Liquid Nanodomains