Quantification of Active Site Density and Turnover Frequency: From Single-Atom Metal to Nanoparticle Electrocatalysts

Bae, Geunsu; Kim, Haesol; Choi, Hansol; Jeong, Pyeonghwa; Kim, Dong Hyun; Kwon, Han Chang; Lee, Kug‐Seung; Choi, Minkee; Oh, Hyung Suk; Jaouen, Frédéric; Choi, Chang Hyuck

doi:10.1021/jacsau.1c00074

Cited by 62 publications

(54 citation statements)

References 79 publications

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“… 10 A few approaches have been used by our community for the explicit determination of the “true” number of active sites, including (1) electrochemical oxidation that yields distinct electrochemical features corresponding to the active edge sites and the inert basal plane sites for MoS 2 catalysts for the HER, 11 (2) the integration of the area below the redox peak for a redox reaction (M ( n +1)+ /M n + ) just before the onset of the OER to estimate the concentration of active sites (M n + ) for 3d transition metal based electrocatalysts, 12 and (3) the use of surface probes like Pb, Cu, CO and CN that selectively adsorb on certain types of active sites ( e.g. undercoordinated sites) that have been used to quantify active site densities for single atom catalysts for the ORR, 13 WS 2 nanosheets for the HER 14 and Au catalysts for the CO 2 RR. 15 …”

Section: We Need Active Site Estimations and Fast Mass Transport To Determine Intrinsic Catalytic Activitymentioning

confidence: 99%

Improving the intrinsic activity of electrocatalysts for sustainable energy conversion: where are we and where can we go?

et al. 2022

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Section: We Need Active Site Estimations and Fast Mass Transport To Determine Intrinsic Catalytic Activitymentioning

confidence: 99%

Improving the intrinsic activity of electrocatalysts for sustainable energy conversion: where are we and where can we go?

et al. 2022

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“…The latter often poses a limit when it comes to signal intensity, especially for electrochemical in situ measurements requiring suitable electrode loadings (commonly <5 mg catalyst cm -2 , i.e., <0.15 mg metal cm -2 -a comparatively low sample amount for spectroscopic measurements) to achieve the high catalyst utilizations needed for reliable spectroscopic results. [53,54] Most crucially, only a low fraction of these MN x C y sites are typically located within the operando-relevant catalystelectrolyte interface (possibly as little as ≈10-20 %, according to recent nitrate-/cyanide-poisoning and in situ MS measurements [36,37,[55][56][57][58] ) thus jeopardizing the interpretation of in situ spectroscopic results that are likely to be preponderantly representative of the materials' bulk composition.…”

Section: Introductionmentioning

confidence: 99%

Time‐Resolved Potential‐Induced Changes in Fe/N/C‐Catalysts Studied by In Situ Modulation Excitation X‐Ray Absorption Spectroscopy

Ebner

Clark

Saveleva

et al. 2022

Advanced Energy Materials

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To advance the widespread implementation of electrochemical energy storage and conversion technologies, the development of inexpensive electrocatalysts is imperative. In this context, Fe/N/C-materials represent a promising alternative to the costly noble metals currently used to catalyze the oxygen reduction reaction (ORR), and also display encouraging activities for the reduction of CO 2 . Nevertheless, the application of these materials in commercial devices requires further improvements in their performance and stability that are currently hindered by a lack of understanding of the nature of their active sites and the associated catalytic mechanisms. With this motivation, herein the authors exploit the high sensitivity of modulation excitation X-ray absorption spectroscopy toward species undergoing potential-induced changes to elucidate the operando local geometry of the active sites in two sorts of Fe/N/C-catalysts. While the ligand environment of a part of both materials' sites appears to change from six-/five-to fourfold coordination upon potential decrease, they differ substantially when it comes to the geometry of the coordination sphere, with the more ORRactive material undergoing more pronounced restructuring. Furthermore, these time-resolved spectroscopic measurements yield unprecedented insights into the kinetics of Fe-based molecular sites' structural reorganization, identifying the oxidation of iron as a rate-limiting process for the less ORR-active catalyst.

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“…Progress has been made on TOF calculations of SACs by measuring active site density using ex situ cryo CO pulse chemisorption and temperature-programmed desorption, [120,121] in situ electrochemical NO 2stripping [122] and, recently, in situ cyanide anion probe. [123] Lower TOF values are obtained with temperature-programmed desorption of CO, as the ex situ adsorbed CO overestimates the number of electrochemically accessible active sites, resulting in a lower calculated TOF. Mössbauer spectroscopy can also probe the total density of specific sites, although deviating from the number of sites accessible for adsorption of O 2 or CO, due to being a bulk characterization technique (Section 4.2.3).…”

Section: Methodsmentioning

confidence: 96%

Dual‐Metal Atom Electrocatalysts: Theory, Synthesis, Characterization, and Applications

Pedersen

Barrio

et al. 2021

Advanced Energy Materials

106

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a required reduction in emissions per unit production of 75% by 2050 in order to have a 50% chance of limiting global mean temperature rise by 2 °C compared to pre-industrial levels. [1,2] Improvements in the field of electrocatalysts, especially in relation to electrolyzers and fuel cells, will help these devices become part of the solution to the looming sustainable energy and chemical production needs. [3] For these devices to be entirely renewable, H 2 (and O 2 ) needs to be produced by water splitting in electrolyzers through H 2 and O 2 evolution (green hydrogen production), rather than from methane reforming (grey hydrogen production). [4,5] H 2 can then be used in electrochemical O 2 reduction in fuel cells to produce electricity. [6,7] Meanwhile, electrochemical reduction of N 2 to NH 3 can provide a sustainable means to a critical fertilization source for the agricultural industry and a carrier for H 2 . [8] Moreover, a way of producing value-added products and a "circular economy" for industry from CO 2 emissions is via the electrocatalytically driven CO 2 reduction, which converts CO 2 to essential feedstocks, such as ethylene or ethanol for the chemical industry. [9] Low-temperature fuel cells and electrolyzers typically utilize catalysts based on platinum group metal (PGM) nanoparticles, [10] which limits device commercialization due to increasing global demand, low uptake of recycling, and high cost of PGMs. [11] Consequently, many researchers have turned their attention to reducing PGM loading or entirely replacing them with lower-cost earth-abundant metals, such as Fe, Cu, Ni, Co, Mn, and, most recently, Sn. [12] Regardless of the catalyst composition, improvements in the electrochemical activity have been highly sought after with two general options available; increasing the number of accessible catalytic sites and/or increasing the intrinsic activity of the catalytic sites. [13] Many different catalyst designs have been explored in order to raise the activity, such as alloying [14] or nanostructuring. [15] While increasing the density of catalytic sites improves activity, this method becomes physically limited when catalyst loading affects charge and mass transport. [13] Thus, improving the activity per catalytic site (intrinsic activity) through controlling local geometry and electronic structure has garnered research attention, with successful methods including shrinking the catalytic site down to atomic scale, as well as locally introducing light heteroatoms or hosting the catalytic site at edges. [10,[16][17][18] Electrochemical clean energy conversion and the production of sustainable chemicals are critical in the journey to realizing a truly sustainable society. To progress electrochemical storage and conversion devices to commercialization, improving the electrocatalyst performance and cost are of utmost importance. Research into dual-metal atom catalysts (DACs) is rising in prominence due to the advantages of these sites over single-metal atom catalysts (SACs), such as breaking scaling ...

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Quantification of Active Site Density and Turnover Frequency: From Single-Atom Metal to Nanoparticle Electrocatalysts

Cited by 62 publications

References 79 publications

Improving the intrinsic activity of electrocatalysts for sustainable energy conversion: where are we and where can we go?

Improving the intrinsic activity of electrocatalysts for sustainable energy conversion: where are we and where can we go?

Time‐Resolved Potential‐Induced Changes in Fe/N/C‐Catalysts Studied by In Situ Modulation Excitation X‐Ray Absorption Spectroscopy

Dual‐Metal Atom Electrocatalysts: Theory, Synthesis, Characterization, and Applications

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