Single-Atom Catalysis: Insights from Model Systems

Abstract: The field of single atom catalysis (SAC) has expanded greatly in recent years. While there has been much success developing new synthesis methods, a fundamental disconnect exists between most experiments and the theoretical computations used to model them. The real catalysts are based on powder supports, which inevitably contain a multitude of different facets, different surface sites, defects, hydroxyl groups, and other contaminants due to the environment. This makes it extremely difficult to determine the st… Show more

“…A dissolution or diffusion of the clusters into the bulk, on the other hand, can be excluded by the only slightly decreasing Pt 4f signal in the more bulk-sensitive measurement at 921 eV photon energy, as well as by the STM measurements (discussed below), which is consistent with previous reports in the literature where neither Pt atoms nor clusters can be incorporated in bulk magnetite. 20,65,67 This experiment already gives insights into the morphology of the encapsulating layer. Although alloying cannot be excluded entirely, the reduction of the signal intensity indicates an additional layer on top of the clusters, which is also in line with the sputtering experiment described above.…”

“…Atomically resolving microscopy combined with highly sensitive reactivity measurements provides unmatched insights into encapsulation and sintering processes on the atomic scale, allowing us to discern whether the clusters remain size-selected or might even be completely integrated into the substrate. Such dynamic effects are increasingly discussed in the literature in the context of single-atom versus cluster catalysis and potential interchange between the two. − In our research, we study the cluster encapsulation and concomitant sintering behavior on the atomic scale with sound statistics and across a wide temperature range, with the aim to enable heterogeneous catalysis at stabilized subnanometer particles under harsh conditions.…”

Does Cluster Encapsulation Inhibit Sintering? Stabilization of Size-Selected Pt Clusters on Fe₃O₄(001) by SMSI

“…A dissolution or diffusion of the clusters into the bulk, on the other hand, can be excluded by the only slightly decreasing Pt 4f signal in the more bulk-sensitive measurement at 921 eV photon energy, as well as by the STM measurements (discussed below), which is consistent with previous reports in the literature where neither Pt atoms nor clusters can be incorporated in bulk magnetite. 20,65,67 This experiment already gives insights into the morphology of the encapsulating layer. Although alloying cannot be excluded entirely, the reduction of the signal intensity indicates an additional layer on top of the clusters, which is also in line with the sputtering experiment described above.…”

“…Atomically resolving microscopy combined with highly sensitive reactivity measurements provides unmatched insights into encapsulation and sintering processes on the atomic scale, allowing us to discern whether the clusters remain size-selected or might even be completely integrated into the substrate. Such dynamic effects are increasingly discussed in the literature in the context of single-atom versus cluster catalysis and potential interchange between the two. − In our research, we study the cluster encapsulation and concomitant sintering behavior on the atomic scale with sound statistics and across a wide temperature range, with the aim to enable heterogeneous catalysis at stabilized subnanometer particles under harsh conditions.…”

Does Cluster Encapsulation Inhibit Sintering? Stabilization of Size-Selected Pt Clusters on Fe₃O₄(001) by SMSI

“…Single-atom catalysts (SACs) are extensively applied for various electrochemical reactions to produce value-added chemicals − due to their high atom utilization efficiency along with their unique properties. − According to their widespread applications, the rational design of SACs has received a lot of interest in improving the feasibility and efficiency of optimizing the desired products. , Density functional theory (DFT) calculations are mostly applied for the rational design of SACs with a focus on high activities and selectivities . However, DFT calculations are computationally expensive and time-consuming , due to the fact that the complexity of structure–activity relationships requires a huge number of nontrivial DFT calculations in a vast dimensional space, such as environmental coordination, SAC type, and reactants .…”

A Surrogate Machine Learning Model for the Design of Single-Atom Catalyst on Carbon and Porphyrin Supports towards Electrochemistry

“…Photocatalysts with atomic metal sites exhibit unique structure and maximum atom efficiency 9 and have been attracted continuous interest. 10−15 In the photocatalytic water oxidation, the activity of metal sites strongly relies on the chemical microstructures composed of metal ions and the surrounding coordination environment.…”

“…Photocatalysts with atomic metal sites exhibit unique structure and maximum atom efficiency and have been attracted continuous interest. − In the photocatalytic water oxidation, the activity of metal sites strongly relies on the chemical microstructures composed of metal ions and the surrounding coordination environment. , The isolated metal site should be less active for dissociation of water and/or O–O bond formation, which is generally rate-limiting. , It is challenging to explore the semiconductor as supporter that can provide synergistic effects to mimic the synergy of multinuclear CaMn 4 O 5 for oxygen evolution in natural photosynthesis . In recent years, organic semiconductors such as C 3 N 4 , , conjugated microporous polymer, − and covalent organic frameworks − have been explored to support atomic metal sites for photocatalytic water oxidation, and they have demonstrated promising activities in O 2 evolution.…”

Photoinduced Hydration Boosts O₂ Evolution on Co-Chelating Covalent Organic Framework