Transplanting Gold Active Sites into Non-Precious-Metal Nanoclusters for Efficient CO<sub>2</sub>-to-CO Electroreduction

Seong, Hoeun; Jo, Yongsung; Efremov, V. I.; Kim, Yujin; Park, Sojung; Han, Seunghak; Chang, Kiyoung; Park, Jiwoo; Choi, Woojun; Kim, Wooyul; Choi, Chang Hyuck; Yoo, Jong Suk; Lee, Dongil

doi:10.1021/jacs.2c09170

Cited by 43 publications

(30 citation statements)

References 56 publications

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“…This study provided evidence for the surface Cd–S–Au synergistic effect involved in CO 2 RR. Au 24 Cd 1 (SR) 18 (Figure c and d) and Au 47 Cd 2 (SR) 31 were successively reported to significantly enhance CO 2 conversion toward CO. , The surface heteroatom doping strategy can be extended to other heteroatom doped clusters such as Au 4 Ni 2 (SR) 8 (Figure e and f). , …”

Section: Catalytic Performances Enhanced By Surface/subsurface Hetero...mentioning

confidence: 93%

“…The determined structural information on nanocluster catalysts imparts advantages in identifying active sites and exploring catalytic mechanisms, which can in turn guide the design and synthesis of high-performance catalysts. More notably, doping foreign metal atoms (i.e., heteroatoms) into a designated nanocluster is an effective strategy for tailoring its catalytic property through modulating the electronic properties, improving the structural robustness, and providing additional active sites for the absorption and activation of reactant molecules. − ,− Given structural characteristic of nanoclusters, the heteroatoms can be introduced into the surface of the parent homometal nanocluster, , in which they can directly act as active sites for improving the catalytic reactivity or cooperatively communicating with organic ligands to form surface multisites to promote the reactions occurring at different sites. The heterometallic atom can also replace the subsurface or kernel atom of the parent nanocluster, in which it can tune the electronic property through the electron transfer of subsurface/kernel heteroatoms to exterior metal atoms or vice versa, thereby imparting a substantial influence on the observed catalytic performance. ,,,, These researches bring about a new conceptual framework for understanding subnanometer-scale catalysis.…”

Section: Key Referencesmentioning

confidence: 99%

Section: Catalytic Performances Enhanced By Surface/subsurface Hetero...mentioning

confidence: 99%

“…Li and co-workers reported a Au 19 Cd 2 (SR) 16 cluster that was prepared by substituting the surface Au atoms of 5c and d) and Au 47 Cd 2 (SR) 31 were successively reported to significantly enhance CO 2 conversion toward CO. 21,37 The surface heteroatom doping strategy can be extended to other heteroatom doped clusters such as Au 4 Ni 2 (SR) 8 (Figure 5e and f). 40,50 Recently, Li and co-workers made an extra effort to identify the active Cu 3 S 3 surface motif of the Cu 12 Ag 17 (SR) 12 (PPh 3 ) 4 cluster for the CO 2 formylation reaction with amines and found that Cu 12 Ag 17 (SR) 12 (PPh 3 ) 4 can integrate the advantages of homogeneous and heterogeneous catalysts, thereby exhibiting highly catalytic activity and recyclability. 2 As shown in Figure 6a, a series of the structurally comparable cluster catalysts including ■ CATALYTIC PERFORMANCES REMOTELY…”

Section: Surface/subsurface Heteroatoms Of Bimetallic Clustersmentioning

confidence: 99%

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Catalysis Synergism by Atomically Precise Bimetallic Nanoclusters Doped with Heteroatoms

2023

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Conspectus Bimetallic catalysts hold promise in tailoring the catalytic activity and selectivity of transition metals for important chemical processes due to the synergistic coupling between the constituent elements that can connect catalytical active sites. However, it remains a challenge to construct an ideal bimetallic catalyst to study the respective or cooperative effects of the two transition metals within the bimetallic catalyst on the overall catalytic performance because multiple factors are always convoluted, such as the size dispersity of particles, the inhomogeneous structure, and the unknown exact location of the two metal elements in any particle. Therefore, almost all of the current studies give rise to the statistics of the overall catalytic performance from all of the particles in a bimetallic catalyst or at least the observed performance reflects an ensemble average of all metal atoms in a particle. Atomically precise metal nanoclusters have attracted catalysis scientists since their total structures (core plus surface) were solved by single-crystal X-ray crystallography, thereby providing unparalleled opportunities to build a precise correlation of catalyst structures with catalytic properties at an atomic level. Within this field, we are interested in identifying catalytically active sites and further constructing the active sites by an atom-by-atom manipulation, which are typically challenging for conventional particle-based heterogeneous catalysts and organometallics-based complex catalysts. In this Account, we mainly focus on the extensive efforts to fundamentally understand catalysis synergy in bimetallic nanocluster catalysts doped with heterometallic atoms. We first briefly describe the design rules and chemical synthesis of atomically precise bimetallic nanoclusters doped with heteroatoms including co-reduction, atom substitution, and reconstruction as typical synthesis strategies. We then put particular emphasis on the recent research toward the synergistic effects of surface/subsurface heteroatoms of the bimetallic nanoclusters on controlling the catalytic pathways, in which a series of examples showed that catalytically active sites can be dramatically tailored by the metal heteroatoms (Ru, Cu, Ni, Cd, etc.) located on the surface or subsurface of gold nanoclusters. Other cases indicated that the catalytic activity can be driven by surface heteroatom–ligand motifs of bimetallic nanoclusters. We also discuss the remote effects of nonsurface or kernel heteroatoms located in the cores of bimetallic nanoclusters on improving the catalytic reactions directly occurring on the catalyst surface. Finally, we anticipate that the advances in this research field would not only provide in-depth insight into the intraparticle synergism in bimetallic catalysts for understanding and controlling their catalytic reactivity but also provide valuable guidelines for high-performance catalysts that can be applied in industry.

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Section: Catalytic Performances Enhanced By Surface/subsurface Hetero...mentioning

confidence: 93%

Section: Key Referencesmentioning

confidence: 99%

Section: Catalytic Performances Enhanced By Surface/subsurface Hetero...mentioning

confidence: 99%

Section: Surface/subsurface Heteroatoms Of Bimetallic Clustersmentioning

confidence: 99%

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Catalysis Synergism by Atomically Precise Bimetallic Nanoclusters Doped with Heteroatoms

2023

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“…Recently, Seong et al developed a remarkable strategy to prepare Au 2 Ni 3 and Au 4 Ni 2 by doping Au atoms into Ni 4 NCs, which made a radical change in catalyst selectivity from the HER to the CO 2 RR. 50 The synthesis route and the crystal structure of Au 2 Ni 3 and Au 4 Ni 2 are shown in Fig. 12A and B, as well as a clarification of the substitution of one nickel atom with two gold atoms.…”

Section: Electrocatalytic Applications Of Ncsmentioning

confidence: 99%

Recent advances in atomically precise metal nanoclusters for electrocatalytic applications

Yuan

Zhu

2023

Inorg. Chem. Front.

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Nanocluster Surface Microenvironment Modulates Electrocatalytic CO₂ Reduction

Yoo,

Deng

et al. 2023

Advanced Materials

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The catalytic activity and product selectivity of the electrochemical CO2 reduction reaction (eCO2RR) depend strongly on the local microenvironment of mass diffusion at the nanostructured catalyst and electrolyte interface. Achieving a molecular‐level understanding of the electrocatalytic reaction requires the development of tunable metal‐ligand interfacial structures with atomic precision, which is highly challenging. Here, the synthesis and molecular structure of a 25‐atom silver nanocluster interfaced with an organic shell comprising 18 thiolate ligands are presented. The locally induced hydrophobicity by bulky alkyl functionality near the surface of the Ag25 cluster dramatically enhances the eCO2RR activity (CO Faradaic efficiency, FECO: 90.3%) with higher CO partial current density (jCO) in an H‐cell compared to Ag25 cluster (FECO: 66.6%) with confined hydrophilicity, which modulates surface interactions with water and CO2. Remarkably, the hydrophobic Ag25 cluster exhibits jCO as high as −240 mA cm−2 with FECO >90% at −3.4 V cell potential in a gas‐fed membrane electrode assembly device. Furthermore, this cluster demonstrates stable eCO2RR over 120 h. Operando surface‐enhanced infrared absorption spectroscopy and theoretical simulations reveal how the ligands alter the neighboring water structure and *CO intermediates, impacting the intrinsic eCO2RR activity, which provides atomistic mechanistic insights into the crucial role of confined hydrophobicity.

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Transplanting Gold Active Sites into Non-Precious-Metal Nanoclusters for Efficient CO₂-to-CO Electroreduction

Cited by 43 publications

References 56 publications

Catalysis Synergism by Atomically Precise Bimetallic Nanoclusters Doped with Heteroatoms

Catalysis Synergism by Atomically Precise Bimetallic Nanoclusters Doped with Heteroatoms

Recent advances in atomically precise metal nanoclusters for electrocatalytic applications

Nanocluster Surface Microenvironment Modulates Electrocatalytic CO₂ Reduction

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Transplanting Gold Active Sites into Non-Precious-Metal Nanoclusters for Efficient CO2-to-CO Electroreduction

Cited by 43 publications

References 56 publications

Catalysis Synergism by Atomically Precise Bimetallic Nanoclusters Doped with Heteroatoms

Catalysis Synergism by Atomically Precise Bimetallic Nanoclusters Doped with Heteroatoms

Recent advances in atomically precise metal nanoclusters for electrocatalytic applications

Nanocluster Surface Microenvironment Modulates Electrocatalytic CO2 Reduction

Contact Info

Product

Resources

About

Transplanting Gold Active Sites into Non-Precious-Metal Nanoclusters for Efficient CO₂-to-CO Electroreduction

Nanocluster Surface Microenvironment Modulates Electrocatalytic CO₂ Reduction