Supported Single Atom and Pseudo‐Single Atom of Metals as Sustainable Heterogeneous Nanocatalysts

Dhiman, Mahak; Polshettiwar, Vivek

doi:10.1002/cctc.201701431

Cited by 38 publications

(17 citation statements)

References 203 publications

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“…Under hydrogenation reaction conditions, the nanometer-sized Pt oxide species can be easily reduced to the metallic state and sintered to Pt particles ( Huizinga et al., 1984 , Duan et al., 2018 ), which will strongly bind the adsorbed H species, resulting in the lack of weakly bound hydrogen species for catalytic reactions. Furthermore, the H 2 dissociation over Pt 1 /h-NCs may follow the heterolytic dissociation procedure to yield H δ+ and H δ− species on the Pt-carbon interface, which may significantly enhance the catalytic activity of hydrogenation reactions as reported in the literature ( Liu et al., 2016 , Wang et al., 2016 , Dhiman and Polshettiwar, 2018 ). The spillover effects of the activated H species over the carbon support cannot be ruled out.…”

Section: Resultsmentioning

confidence: 87%

Nanocarbon-Edge-Anchored High-Density Pt Atoms for 3-nitrostyrene Hydrogenation: Strong Metal-Carbon Interaction

Lou

Liu

2019

iScience

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SummaryStrong metal-support interaction (SMSI) has been widely used to improve catalytic performance and to identify reaction mechanisms. We report that single Pt atoms anchored onto hollow nanocarbon (h-NC) edges possess strong metal-carbon interaction, which significantly modifies the catalytic behavior of the anchored Pt atoms for selective hydrogenation reactions. The strong Pt-C bonding not only stabilizes single Pt atoms but also modifies their electronic structure, tunes their adsorption properties, and enhances activation of reactants. The fabricated Pt1/h-NC single-atom catalysts (SACs) demonstrated excellent activity for hydrogenation of 3-nitrostyrene to 3-vinylaniline with a turnover number >31,000/h, 20 times higher than that of the best catalyst for such selective hydrogenation reactions reported in the literature. The strategy to strongly anchor Pt atoms by edge carbon atoms of h-NCs is general and can be extended to construct strongly anchored metal atoms, via SMSI, onto surfaces of various types of support materials to develop robust SACs.

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Section: Resultsmentioning

confidence: 87%

Nanocarbon-Edge-Anchored High-Density Pt Atoms for 3-nitrostyrene Hydrogenation: Strong Metal-Carbon Interaction

Lou

Liu

2019

iScience

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“…[1,4,5] The catalytic activity and selectivity of SACs not only depend on the nature of the single atom but also on the solid supports that are used to disperse the metal. [6] Therefore, it is essential to…”

Section: Heteroatom-mediated Interactions Between Ruthenium Single Atmentioning

confidence: 99%

“…Thus far, graphene nanosheets, carbon nanotubes, and other carbon materials and metal oxides have been widely used as supports for SACs. [5][6][7] Unfortunately, these materials tend to be either poor electrical conductors, electrochemically inert, or hydrophobic, which hampers the practical application of SACs for water-based electrochemical reactions. [8,9] Thus, it is crucial to identify a solid support with excellent conductivity that is also electrochemically active and hydrophilic in order to better host isolated single atoms for electrocatalytic applications.…”

Section: A Titanium Carbide (Ti 3 C 2 T X ) Mxene Is Employed As An Ementioning

confidence: 99%

Heteroatom‐Mediated Interactions between Ruthenium Single Atoms and an MXene Support for Efficient Hydrogen Evolution

et al. 2019

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A titanium carbide (Ti3C2Tx) MXene is employed as an efficient solid support to host a nitrogen (N) and sulfur (S) coordinated ruthenium single atom (RuSA) catalyst, which displays superior activity toward the hydrogen evolution reaction (HER). X‐ray absorption fine structure spectroscopy and aberration corrected scanning transmission electron microscopy reveal the atomic dispersion of Ru on the Ti3C2Tx MXene support and the successful coordination of RuSA with the N and S species on the Ti3C2Tx MXene. The resultant RuSA‐N‐S‐Ti3C2Tx catalyst exhibits a low overpotential of 76 mV to achieve the current density of 10 mA cm−2. Furthermore, it is shown that integrating the RuSA‐N‐S‐Ti3C2Tx catalyst on n+np+‐Si photocathode enables photoelectrochemical hydrogen production with exceptionally high photocurrent density of 37.6 mA cm−2 that is higher than the reported precious Pt and other noble metals catalysts coupled to Si photocathodes. Density functional theory calculations suggest that RuSA coordinated with N and S sites on the Ti3C2Tx MXene support is the origin of this enhanced HER activity. This work would extend the possibility of using the MXene family as a solid support for the rational design of various single atom catalysts.

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“…[23,[30][31] However, it is a great challenge to prepare SACs with high metal loading, since the high surface energy makes the atomically dispersed metal atoms aggregate easily. [32] Several review papers have summarized various synthesis methods, [33][34][35] including the wet-chemistry method, [20] atomic layer deposition (ALD) method, [36][37] anti-Ostwald ripening, [38][39] ball milling, [40] and mass selection with softlanding. [41] None of these reviews focus on the preparation of high metal loading SACs.…”

Section: Introductionmentioning

confidence: 99%

Synthesis of High Metal Loading Single Atom Catalysts and Exploration of the Active Center Structure

Wang

Liu

2020

ChemCatChem

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Single‐atom catalysts (SACs) have been rising recently as a new frontier in the catalysis field. Due to maximum atom utilization efficiency and tunable electronic structures, SACs exhibit highly distinctive catalytic performance from bulk counterparts. SACs with high metal loading will facilitate practical applications. To that end, this Review focuses on recent strategies to maximize metal loading. An appropriate substrate, mainly heteroatom‐doped carbon materials, is the key to avoiding aggregation or sintering during synthetic procedures. The coordination site construction and spatial confinement strategies are adopted to prepare SACs with high metal loading. Advanced characterization techniques with atomic resolution are indispensable for identification of the exact structure of SACs. This is true, especially for the applications and challenges in developing in situ/operando characterization techniques at the atomic level, which are discussed in this Review. Moreover, it is fundamentally necessary to investigate the active center structure, which facilitates any design of efficient SACs that can maximize single‐atom catalytic activity. Furthermore, this Review highlights challenges and prospects for development of SACs.

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Supported Single Atom and Pseudo‐Single Atom of Metals as Sustainable Heterogeneous Nanocatalysts

Cited by 38 publications

References 203 publications

Nanocarbon-Edge-Anchored High-Density Pt Atoms for 3-nitrostyrene Hydrogenation: Strong Metal-Carbon Interaction

Nanocarbon-Edge-Anchored High-Density Pt Atoms for 3-nitrostyrene Hydrogenation: Strong Metal-Carbon Interaction

Heteroatom‐Mediated Interactions between Ruthenium Single Atoms and an MXene Support for Efficient Hydrogen Evolution

Synthesis of High Metal Loading Single Atom Catalysts and Exploration of the Active Center Structure

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