Reactivity of Single-Atom Alloys as Easy as Counting to Ten

Schumann, Julia; Stamatakis, Michail; Michaelides, Angelos; Réocreux, Romain

doi:10.26434/chemrxiv-2022-d5hhf

Cited by 3 publications

(7 citation statements)

References 30 publications

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“…Although all the above-mentioned approaches are valuable for understanding SAC reactivity, they still require expensive and complex simulations that are not easily accessible to researchers attempting to design efficient SACs for a specific reaction. Lately, an uncommonly simple molecular orbital approach has been proposed for SAAs based on the key concept that the interaction of adsorbates at their surface can be described in terms of an electron counting rule . By combining machine learning and DFT analyses, a variety of catalytically relevant adsorbates was screened on a large set of SAA surfaces, showing that the adsorbate interaction with the isolated metal site is maximized when the n d valence electrons of the dopant and the k valence electrons of the adsorbates sum up to 10: n d + k = 10.…”

Section: Characterization Approachesmentioning

confidence: 99%

“…Lately, an uncommonly simple molecular orbital approach has been proposed for SAAs based on the key concept that the interaction of adsorbates at their surface can be described in terms of an electron counting rule. 17 By combining machine learning and DFT analyses, a variety of catalytically relevant adsorbates was screened on a large set of SAA surfaces, showing that the adsorbate interaction with the isolated metal site is maximized when the n d valence electrons of the dopant and the k valence electrons of the adsorbates sum up to 10: n d + k = 10. Undoubtedly, this simple 10-electron rule provides experimentalists with a straightforward tool to identify suitable metal combinations when designing SAAs for targeted applications.…”

Section: Characterization Approachesmentioning

confidence: 99%

“…Nonetheless, as highlighted by several recent works, ,− the performance of SACs can significantly differ from that of extended metal surfaces, calling for a reanalysis of the suitability of existing general models, e.g., to account for local charges or spin polarization. Beyond heterogeneous catalysts, researchers frequently highlight the resemblance of SACs to organometallic complexes and have explored descriptors such as molecular orbitals and oxidation states. , However, it has also been shown that the coordination of metal atoms to solid supports can differ in nature, compared to ligands, , and the impacts are not yet fully understood.…”

Section: Introductionmentioning

confidence: 99%

“…Beyond heterogeneous catalysts, researchers frequently highlight the resemblance of SACs to organometallic complexes and have explored descriptors such as molecular orbitals and oxidation states. 17 , 18 However, it has also been shown that the coordination of metal atoms to solid supports can differ in nature, compared to ligands, 18 , 19 and the impacts are not yet fully understood.…”

Section: Introductionmentioning

confidence: 99%

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Challenges and Opportunities in Engineering the Electronic Structure of Single-Atom Catalysts

2023

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Controlling the electronic structure of transition-metal single-atom heterogeneous catalysts (SACs) is crucial to unlocking their full potential. The ability to do this with increasing precision offers a rational strategy to optimize processes associated with the adsorption and activation of reactive intermediates, charge transfer dynamics, and light absorption. While several methods have been proposed to alter the electronic characteristics of SACs, such as the oxidation state, band structure, orbital occupancy, and associated spin, the lack of a systematic approach to their application makes it difficult to control their effects. In this Perspective, we examine how the electronic configuration of SACs can be engineered for thermochemical, electrochemical, and photochemical applications, exploring the relationship with their activity, selectivity, and stability. We discuss synthetic and analytical challenges in controlling and discriminating the electronic structure of SACs and possible directions toward closing the gap between computational and experimental efforts. By bringing this topic to the center, we hope to stimulate research to understand, control, and exploit electronic effects in SACs and ultimately spur technological developments.

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Section: Characterization Approachesmentioning

confidence: 99%

Section: Characterization Approachesmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Challenges and Opportunities in Engineering the Electronic Structure of Single-Atom Catalysts

2023

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“…When coverage effects are negligible, two factors influence the binding energies of adsorbates at the dopant site on SAAs: the atomic charge of the dopant and the number of valence electrons of the dopant. 27 In the limiting case of adsorption governed by electrostatic contributions (e.g., H 2 O and OH), the atomic charge of the dopant is, on its own, a good qualitative descriptor for the SOE. Because of the negative partial charges of the oxygen atoms with which the formate binds to the surface, we would expect that dopants with less negative charges would interact more favorably with formate.…”

mentioning

confidence: 99%

Investigating Spillover Energy as a Descriptor for Single-Atom Alloy Catalyst Design

Hannagan,

Lam,

Réocreux

et al. 2023

J. Phys. Chem. Lett.

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The identification of thermodynamic descriptors of catalytic performance is essential for the rational design of heterogeneous catalysts. Here, we investigate how spillover energy, a descriptor quantifying whether intermediates are more stable at the dopant or host metal sites, can be used to design single-atom alloys (SAAs) for formic acid dehydrogenation. Using theoretical calculations, we identify NiCu as a SAA with favorable spillover energy and demonstrate that formate intermediates produced after the initial O−H activation are more stable at Ni sites where ratedetermining C−H activation occurs. Surface science experiments demonstrated that NiCu(111) SAAs are more reactive than Cu(111) while they still follow the formate reaction pathway. However, reactor studies of silica-supported NiCu SAA nanoparticles showed only a modest improvement over Cu resulting from surface coverage effects. Overall, this study demonstrates the potential of engineering SAAs using spillover energy as a design parameter and highlights the importance of adsorbate−adsorbate interactions under steady-state operation.

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Electrochemical Potential-Driven Shift of Frontier Orbitals in M–N–C Single-Atom Catalysts Leading to Inverted Adsorption Energies

Liu,

Luo,

2023

J. Am. Chem. Soc.

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Electronic structure is essential to understanding the catalytic mechanism of metal single-atom catalysts (SACs), especially under electrochemical conditions. This study delves into the nuanced modulation of "frontier orbitals" in SACs on nitrogen-doped graphene (N−C) substrates by electrochemical potentials. We observe shifts in Fermi level and changes of d-orbital occupation with alterations in electrochemical potentials, emphasizing a synergy between the discretized atomic orbitals of metals and the continuous bands of the N−C based environment. Using O 2 and CO 2 as model adsorbates, we highlight the direct consequences of these shifts on adsorption energies, unveiling an intriguing inversion of adsorption energies on Co/N−C SAC under negative electrochemical potentials. Such insights are attributed to the role of the d xz and d z 2 orbitals, pivotal for stabilizing the π* orbitals of O 2 . Through this exploration, our work offers insights on the interplay between electronic structures and adsorption behaviors in SACs, paving the way for enhanced catalyst design strategies in electrochemical processes.

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Reactivity of Single-Atom Alloys as Easy as Counting to Ten

Cited by 3 publications

References 30 publications

Challenges and Opportunities in Engineering the Electronic Structure of Single-Atom Catalysts

Challenges and Opportunities in Engineering the Electronic Structure of Single-Atom Catalysts

Investigating Spillover Energy as a Descriptor for Single-Atom Alloy Catalyst Design

Electrochemical Potential-Driven Shift of Frontier Orbitals in M–N–C Single-Atom Catalysts Leading to Inverted Adsorption Energies

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