Engineering the Electrochemical Interface of Oxygen Reduction Electrocatalysts with Ionic Liquids: A Review

Favero, Silvia; Stephens, Ifan E. L.; Titirici, Maria‐Magdalena

doi:10.1002/aesr.202000062

Cited by 16 publications

(15 citation statements)

References 139 publications

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“…Oxygenophilic and hydrophobic ionic liquids, such as those used as coatings on the surface of electrocatalysts, can modify the triple-point interface, improving oxygen concentration and water expulsion. A recent review by our group has summarized the unexplored potential of ionic liquid layers …”

Section: Bioinspired Interfaces and Mass Transportmentioning

confidence: 99%

“…A recent review by our group has summarized the unexplored potential of ionic liquid layers. 412 Hydrophobicity also has a positive, and perhaps an even more drastic, effect on CO 2 reduction due to (1) the low solubility of CO 2 (33 mM) in aqueous electrolytes causing a mass-diffusion limitation for CO 2 to the electrode surface 413 and (2) the competition with the more thermodynamically favorable HER. In nature, hydrophobicity is utilized to solve these issues; for example, active sites in enzymes such as CODHs/acetyl-CoA synthase are protected by the presence of a hydrophobic protein framework.…”

Section: Nature Offers Several Examples Of How Chemical Compositionmentioning

confidence: 99%

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Bioinspired and Bioderived Aqueous Electrocatalysis

et al. 2022

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The development of efficient and sustainable electrochemical systems able to provide clean-energy fuels and chemicals is one of the main current challenges of materials science and engineering. Over the last decades, significant advances have been made in the development of robust electrocatalysts for different reactions, with fundamental insights from both computational and experimental work. Some of the most promising systems in the literature are based on expensive and scarce platinum-group metals; however, natural enzymes show the highest per-site catalytic activities, while their active sites are based exclusively on earth-abundant metals. Additionally, natural biomass provides a valuable feedstock for producing advanced carbonaceous materials with porous hierarchical structures. Utilizing resources and design inspiration from nature can help create more sustainable and cost-effective strategies for manufacturing cost-effective, sustainable, and robust electrochemical materials and devices. This review spans from materials to device engineering; we initially discuss the design of carbon-based materials with bioinspired features (such as enzyme active sites), the utilization of biomass resources to construct tailored carbon materials, and their activity in aqueous electrocatalysis for water splitting, oxygen reduction, and CO 2 reduction. We then delve in the applicability of bioinspired features in electrochemical devices, such as the engineering of bioinspired mass transport and electrode interfaces. Finally, we address remaining challenges, such as the stability of bioinspired active sites or the activity of metal-free carbon materials, and discuss new potential research directions that can open the gates to the implementation of bioinspired sustainable materials in electrochemical devices.

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Section: Bioinspired Interfaces and Mass Transportmentioning

confidence: 99%

Section: Nature Offers Several Examples Of How Chemical Compositionmentioning

confidence: 99%

Bioinspired and Bioderived Aqueous Electrocatalysis

et al. 2022

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“…In addition, recently, a novel approach based on the use of ionic liquid (IL) such as [BMIM][NTf 2 ], [MTDB][BETI], [DEMA][TfO], etc. to engineer the electrochemical triple-point interface (catalyst–electrolyte–reactant) of both PGM and non-PGM-based catalysts has emerged as a promising alternative under the umbrella of “Solid Catalyst with Ionic Liquid Layer (SCILL)” to boost ORR activity in acidic and alkaline media. − The implementation of this approach is to modify the electrocatalysts by coating their inner surface with a controlled amount of ILs, which have attracted special attention in electrochemistry owing to their high ionic conductivity, broad electrochemical window, and good chemical stability . Furthermore, the ILs with fluorinated side chains of the anionic parts are also hydrophobic in nature in addition to having higher O 2 solubility due to the strong affinity of fluorines for oxygen, two desirable properties in ORR electrocatalysts .…”

Section: Introductionmentioning

confidence: 99%

“…This composite material (catalyst + IL) design approach exploits the higher oxygen solubility and hydrophobicity of the IL confined within pores, facilitating a higher frequency of interactions of oxygen with the catalyst surface with simultaneous expulsion of product water . The application of IL has also been shown to increase ORR kinetics through effective suppression of the formation of nonreactive oxygenated species and reduced adsorption of OH intermediates, exposing more active sites available for oxygen adsorption. , Thus, a thin layer of an IL as an additive acts by ensuring high oxygen (reactant) concentration and hydrophobicity (product expulsion) at the active sites in addition to weakening the bond to the OH* intermediate, facilitating overall ORR kinetics. ,− The enhanced ORR performance of electrocatalysts modified with [BMIM][NTf 2 ] has been reported, which was attributed to the hydrophobicity of the IL-suppressing catalyst poisoning by oxygenated species . Qiao et al have reported the improved ORR activity of the nitrogen-doped graphene (GN) electrocatalyst through IL modifications of the interface using 20 wt % (of catalyst wt) of [BMIM][NTf 2 ] and [EMIM][NTf 2 ] in 0.1 M HClO 4 and 0.1 M KOH .…”

Section: Introductionmentioning

confidence: 99%

Design and Performance Enhancement of Cobalt-Encapsulated Nitrogen-Doped Carbon Nanofiber Electrocatalyst through Ionic Liquid Modification for Efficient Oxygen Reduction

Parida

Ganguly

Barik

et al. 2023

ACS Appl. Nano Mater.

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The design of platinum-group-metal-free (PGM-free) electrocatalysts with appreciable activity and durability toward the oxygen reduction reaction (ORR) in acidic environments is a big challenge. Here, we report an efficient oxygen reduction activity of a Co-encapsulated nitrogen-doped carbon with nanofiber networks and its ionic liquid-modified interface in an acidic medium. The robust structure of the nanofibers embedded on a rigid framework derived from a zeolitic imidazole framework (ZIF-67) delivers promising activity and durability to the catalyst comparable to the state-of-the-art Pt/C. The ionic-liquid-modified catalyst shows a half-wave potential of 0.71 V vs RHE in oxygen-saturated 0.5 M H2SO4 along with activity reduction by only 11 mV (E 1/2) after 5000 cycles of the accelerated durability test. The catalyst also retains 71% of its original current during the short-term durability test. Furthermore, the electron transfer number and H2O2 yield of the catalyst during the ORR approaches 3.88–3.90 and 5.9–4.8% in the potential range 0.4–0.7 V vs RHE. The ORR performance of the ionic-liquid-modified catalyst is superior among all ionic liquid-based non-PGM catalysts reported so far in acidic media.

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“…27 Oxygen solubility results reported in different manuscripts [27][28][29][30][31][32][33][34] display large variations, with a percentage error of up to 60% (Figure S6a). 26 Moreover, to the best of our knowledge, results obtained with different experimental techniques have never been compared in a single study. 27,31,32,35 Most studies neglect the difference between O2 concentration and thermodynamic activity, which is inappropriate for oxygenophilic ionic liquids.…”

Section: Introductionmentioning

confidence: 99%

Deconvoluting Kinetics and Transport Effects of Ionic Liquid Layers on FeN4-based Oxygen Reduction Catalysts

Favero

Stephens

Titirici

2023

Preprint

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The use of ionic liquid layers has been reported to improve both the activity and durability of several oxygen reduction catalysts. However, the development of this technology has been hindered by the lack of understanding of the mechanism behind this performance enhancement. In this work, we use a library of ionic liquids to modify a model FeN4 catalyst (iron phthalocyanine), to decouple the effects of ionic liquid layers on oxygen reduction kinetics and oxygen transport. Our results show that oxygen reduction activity at low overpotentials it determined by the ionic liquids’ influence on the *OH binding energy on the active sites, while oxygen solubility controls transport at high overpotentials. Finally, using porosimetry, we have demonstrated that the distribution of the ionic liquids on the catalyst is inhomogeneous, and depends on the nature of the ionic liquid used.

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Engineering the Electrochemical Interface of Oxygen Reduction Electrocatalysts with Ionic Liquids: A Review

Cited by 16 publications

References 139 publications

Bioinspired and Bioderived Aqueous Electrocatalysis

Bioinspired and Bioderived Aqueous Electrocatalysis

Design and Performance Enhancement of Cobalt-Encapsulated Nitrogen-Doped Carbon Nanofiber Electrocatalyst through Ionic Liquid Modification for Efficient Oxygen Reduction

Deconvoluting Kinetics and Transport Effects of Ionic Liquid Layers on FeN4-based Oxygen Reduction Catalysts

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