pH Effects on the Selectivity of the Electrocatalytic CO<sub>2</sub> Reduction on Graphene-Embedded Fe–N–C Motifs: Bridging Concepts between Molecular Homogeneous and Solid-State Heterogeneous Catalysis

Varela, Ana Sofía; Kroschel, Matthias; Leonard, Nathaniel; Ju, Wen; Steinberg, Julian; Bagger, Alexander; Rossmeisl, Jan; Strasser, Peter

doi:10.1021/acsenergylett.8b00273

Cited by 190 publications

(232 citation statements)

References 63 publications

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“…Most of the CO2RR studies are carried out in 0.1 M KHCO 3 electrolyte which has a lower buffer capacity resulting in a higher local pH in comparison with KH 2 PO 4 / K 2 HPO 4 buffer. [24] By contrast, the selectivity towards CH 4 is higher than that reported on other MNC catalysts (Table S1). [24] Our results, however, are comparable with those obtained in KH 2 PO 4 /K 2 HPO 4 buffer.…”

Section: Resultsmentioning

confidence: 62%

“…[13] The activity, however, was dramatically increased by incorporation of a metal to the NÀ C structure. [24] Combined DFT and experimental studies have found that the high binding energy of the FeN x centers towards CO and CO 2 is responsible for the early CO onset potential on FeNC catalyst. Furthermore, the metal center has been shown to have a crucial role on determining the catalytic performance.…”

Section: Introductionmentioning

confidence: 99%

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Optimizing FeNC Materials as Electrocatalysts for the CO₂ Reduction Reaction: Heat‐Treatment Temperature, Structure and Performance Correlations

et al. 2019

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The direct CO 2 electrochemical reduction reaction (CO2RR) into carbon-based chemicals has attracted tremendous attention as a sustainable process for CO 2 utilization. The viability of the process, however, is contingent on finding efficient catalysts based on earth abundant elements. Carbon-based solid catalyst materials doped with nitrogen and transition metals (MÀ NÀ C) have emerged as a cost-efficient alternative for the direct electrochemical reduction of CO 2 into CO. These materials contain different N functionalities and MN x moieties which could be involved in the catalytic process. With the aim of gaining insight into the role of these different active sites and how to control their concentration we have prepared 5 polyani-line derived FeNC catalysts by changing the temperature of the heat treatment (750-1050°C). We observed that it is possible to tune the ratio of the different N functionalities by changing the pyrolysis temperature. Furthermore, this had a clear impact on the catalytic performance of this family of FeNC materials. In particular, a higher temperature correlated with a larger FeN x concentration resulting in a high selectivity toward the CO2RR. These results indicate that FeN x moieties play a predominant role in the catalytic process and that the incorporation of such sites to the carbon structure is enhanced by the heat-treatment temperature.

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Section: Resultsmentioning

confidence: 62%

Section: Introductionmentioning

confidence: 99%

Optimizing FeNC Materials as Electrocatalysts for the CO₂ Reduction Reaction: Heat‐Treatment Temperature, Structure and Performance Correlations

et al. 2019

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“…[32][33][34] We therefore define the applied potential to overcome the maximum energy barriers as the overpotentials (η) for CO 2 RR or HER. [32][33][34] We therefore define the applied potential to overcome the maximum energy barriers as the overpotentials (η) for CO 2 RR or HER.…”

Section: Reaction Pathways and Scaling Relationshipmentioning

confidence: 99%

Catalytic Mechanisms and Design Principles for Single‐Atom Catalysts in Highly Efficient CO₂ Conversion

Gong

Zhang

Lin

et al. 2019

Advanced Energy Materials

177

122

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energy such as wind and solar energy has attracted enormous interest for its significant roles in mitigating CO 2 emissions and reducing dependence on petrochemicals. [1,2] At the heart of the CO 2 conversion technology, electrocatalysts are needed to promote a critical reaction, CO 2 reduction reaction (CO 2 RR) that determines the efficiency and selectivity. To date, the electrocatalysts have confronted severe bottlenecks issue: poor selectivity about various accessory products in CO 2 conversion process, and loss of efficiency toward competing hydrogen evolution. [3] The former involves associated multielectron transfer process and is difficult to accurately control the reaction process by external conditions, [4] while the latter is mainly due to the fact that the equilibrium potentials for most of the CO 2 RR are very close to hydrogen evolution reaction (HER) toward undesirable side-products in aqueous electrolytes, which degrades the electrocatalytic performance during the CO 2 RR process. [5,6] Therefore, CO 2 RR is much more complex than other energy-related electrochemical reactions such as oxygen reduction reaction (ORR) and oxygen evolution reaction (OER), and it is still a great challenge to design and synthesize electrocatalytic materials with higher product selectivity and catalytic activity for CO 2 RR.Among the electrocatalysts including metals oxides and metal-doped carbon materials, single-atom catalysts (SACs) represent an exciting class of catalysts with monodispersed metal catalytic centers and have emerged as the frontier science in both homogeneous and heterogeneous catalysis, including CO 2 conversion. [7][8][9][10] This type of catalysts contains M-N-C moiety with single atoms and is common in building metalorganic frameworks (MOFs), [11] covalent organic frameworks (COFs) [12] with transition metal macrocyclic clusters, such as porphyrin, phthalocyanine, and tetraazannulene, as well as metal-doped carbon materials [13] (e.g., graphene, carbon nanotubes, fullerene). In nature, the biomolecules, like chlorophyll (Mg-porphyrin) in leaves, and iron porphyrins in cytochrome c oxidase in blood cells, have similar structures as SACs, with special ability in photosynthesis and transforming CO 2 from cells with high efficiency and selectivity. [14] Through the selection of appropriate motifs, the construction principles of Direct conversion of CO 2 into carbon-neutral fuels or industrial chemicals holds a great promise for renewable energy storage and mitigation of greenhouse gas emission. However, experimentally finding an electrocatalyst for specific final products with high efficiency and high selectivity poses serious challenges due to multiple electron transfer, complicated intermediates, and numerous reaction pathways in electrocatalytic CO 2 reduction. Here, an intrinsic descriptor that correlates the catalytic activity with the topological, bonding, and electronic structures of catalytic centers on M-N-C based single-atom catalysts is discovered. The "volcano"-shaped relationships betwee...

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“…Combined with experimental measurements and DFT calculations, they found that at low overpotential regime (>−0.45 eV), potential‐determining step is the first proton‐coupled electron transfer reduction of CO 2 to adsorbed COOH; at the intermediate overpotential regime around −0.6 Vs RHE, CO turn‐over frequency (TOF) is linearly related to the CO binding energy: stronger CO binding corresponds to higher CO TOF, indicating COOH* → CO* being the rate‐determining step; at large overpotential regime <−0.7 versus RHE, Co‐ and Mn‐based catalysts start to strongly catalyze the hydrogen evolution reaction, while the Ni‐ and Cu‐based catalysts exhibit very weak binding of H* which makes the HER unfavorable and both high CO selectivity and reactivity can be obtained for Ni‐based catalysts. Meanwhile, Varela et al focused on the origin of the pH effects on the selectivity. They found that the CO formation rate is independent of the pH at fixed potential versus NHE, in consistency with a proton‐decoupled electron‐transfer pathway in which the reduction of CO 2 to CO occurs via a CO 2 − * intermediate, suggesting a decoupled elementary proton−electron transfer mechanism (Figure b,c).…”

Section: Co2r Reactionmentioning

confidence: 99%

The electronic structure underlying electrocatalysis of two‐dimensional materials

Zhao

Shi

et al. 2019

WIREs Comput Mol Sci

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The understanding and development of advanced electrochemical catalysts have attracted intensive studies and achieved tremendous progress in the past decades. Two‐dimensional (2D) materials, such as doped graphene and atomically‐thin transition metal compounds, have shown great promise as electrocatalysts for various renewable energy conversion and storage reactions. Their further developments require improved understanding of the catalytic mechanisms at atomic level. Currently, most of the understandings are based on the formation free energies of the intermediates, which are determined by their binding strengths with the catalyst, usually calculated from density functional theory (DFT). These energies/binding strengths have been used as descriptor to describe the activity of many catalysts. However, it remains less explored why different catalysts have different binding strengths and what are the underlying factors controlling them, requiring studies going beyond atomic level to electronic level. This review aims to provide such links, focusing on 2D electrocatalysts for hydrogen evolution reaction (HER), oxygen reduction reaction/oxygen evolution reaction (ORR/OER), CO2 reduction reaction (CO2R) and nitrogen reduction reaction (NRR). We also discuss some of the significant issues that need to be addressed in DFT calculations, including the effects of varying charge and fixed potential of the catalyst, the passivation of active sites, and the solvation effects. This article is categorized under: Structure and Mechanism > Reaction Mechanisms and Catalysis Structure and Mechanism > Computational Materials Science

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pH Effects on the Selectivity of the Electrocatalytic CO₂ Reduction on Graphene-Embedded Fe–N–C Motifs: Bridging Concepts between Molecular Homogeneous and Solid-State Heterogeneous Catalysis

Cited by 190 publications

References 63 publications

Optimizing FeNC Materials as Electrocatalysts for the CO₂ Reduction Reaction: Heat‐Treatment Temperature, Structure and Performance Correlations

Optimizing FeNC Materials as Electrocatalysts for the CO₂ Reduction Reaction: Heat‐Treatment Temperature, Structure and Performance Correlations

Catalytic Mechanisms and Design Principles for Single‐Atom Catalysts in Highly Efficient CO₂ Conversion

The electronic structure underlying electrocatalysis of two‐dimensional materials

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pH Effects on the Selectivity of the Electrocatalytic CO2 Reduction on Graphene-Embedded Fe–N–C Motifs: Bridging Concepts between Molecular Homogeneous and Solid-State Heterogeneous Catalysis

Cited by 190 publications

References 63 publications

Optimizing FeNC Materials as Electrocatalysts for the CO2 Reduction Reaction: Heat‐Treatment Temperature, Structure and Performance Correlations

Optimizing FeNC Materials as Electrocatalysts for the CO2 Reduction Reaction: Heat‐Treatment Temperature, Structure and Performance Correlations

Catalytic Mechanisms and Design Principles for Single‐Atom Catalysts in Highly Efficient CO2 Conversion

The electronic structure underlying electrocatalysis of two‐dimensional materials

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Product

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pH Effects on the Selectivity of the Electrocatalytic CO₂ Reduction on Graphene-Embedded Fe–N–C Motifs: Bridging Concepts between Molecular Homogeneous and Solid-State Heterogeneous Catalysis

Optimizing FeNC Materials as Electrocatalysts for the CO₂ Reduction Reaction: Heat‐Treatment Temperature, Structure and Performance Correlations

Optimizing FeNC Materials as Electrocatalysts for the CO₂ Reduction Reaction: Heat‐Treatment Temperature, Structure and Performance Correlations

Catalytic Mechanisms and Design Principles for Single‐Atom Catalysts in Highly Efficient CO₂ Conversion