Single-atom Catalysis Using Pt/Graphene Achieved through Atomic Layer Deposition

Sun, Shuhui; Zhang, Gaixia; Gauquelin, Nicolas; Chen, Ning; Zhou, Jigang; Yang, Songlan; Chen, Weifeng; Meng, Xiangbo; Geng, Dongsheng; Banis, Mohammad Norouzi; Li, Ruying; Ye, Siyu; Knights, Shanna; Botton, Gianluigi A.; Sham, Tsun‐Kong; Sun, Xueliang

doi:10.1038/srep01775

Cited by 786 publications

(710 citation statements)

References 34 publications

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“…4 Using X-ray absorption fine structure analyses, they showed that the low-coordination and partially unoccupied densities of states of the Pt 5d orbitals are responsible for the excellent performance. Therefore, CO adsorption energy on atom-type Pt catalysts is generally greater than that on Pt particles and their corresponding extended surfaces.…”

Section: Co Adsorption On Carbon-supported Pt Atom and Dimermentioning

confidence: 99%

“…Single atom catalysts, by providing single active sites at the solid surface, exhibit many fascinating characteristics, such as high activity, selectivity, and maximum atomic utilization as compared to conventional metal catalysts. [4][5][6] In a Pt/C catalyst, the carbon support plays an important role in determining the size and degree of catalyst dispersion. Due to high surface-to-volume ratio (theoretical value of 2630 m 2 /g), graphene is a promising candidate as a substrate for stabilizing metal nanoparticles in heterogeneous catalysis.…”

Section: Introductionmentioning

confidence: 99%

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Influence of Carbon Support on Electronic Structure and Catalytic Activity of Pt Catalysts: Binding to the CO Molecule

2016

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Single-atom catalysts, especially with single Pt atoms, exhibit potentially improved catalytic activity as compared to metal clusters and metal surfaces. Here, the atop and bridged bondings of the CO molecule on the Pt/C system are studied. Vibrational frequencies, Mulliken populations, charge transfer, charge density differences and density of states are examined to determine the influence of the carbon support on electronic properties and catalytic activity of the Pt adatom and dimer. Comparing orbital populations and the amount of electron transfer to/from the CO molecule show that the net amount of electron transfer to the anti-bonding 2π * orbitals of the CO molecule is higher for the supported Pt dimer than for the substrate-free Pt dimer which leads to a lower vibrational frequency and a larger C−O bond distance. The hybridization between the π orbitals of the polycyclic aromatic hydrocarbons surface and the d orbitals of the Pt adatoms is responsible for enhancing the back donation of electrons to the 2π * orbitals of the CO molecule which results in a larger peak below the Fermi level for the 2π * states of the CO molecule in the corresponding density of state analysis. Therefore, it can be concluded that the carbon support significantly enhances the catalytic activity of the Pt atoms in contact with the surface for activating the CO molecule. The calculated C−O vibrational stretching frequencies provide valuable guidance for experiments considering the use of atom-type catalyst as building blocks for designing new catalysts.

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Section: Co Adsorption On Carbon-supported Pt Atom and Dimermentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Influence of Carbon Support on Electronic Structure and Catalytic Activity of Pt Catalysts: Binding to the CO Molecule

2016

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“…It is generally understood that the anodic peak in the reverse scan to be linked to the removal of incompletely oxidized carbonaceous species accumulated on the catalyst surface during the forward anodic scan. 2,36 CO is an intermediate species of methanol oxidation and can poison the Pt catalyst, leading to a lower fuel cell potential and energy conversion efficiency. 2 Therefore, the ratio of the forward anodic peak current density to the backward anodic peak current density (I f /I b ) can be used to indicate the CO tolerance of the catalyst.…”

Section: Electrochemical Performancementioning

confidence: 99%

“…2,36 CO is an intermediate species of methanol oxidation and can poison the Pt catalyst, leading to a lower fuel cell potential and energy conversion efficiency. 2 Therefore, the ratio of the forward anodic peak current density to the backward anodic peak current density (I f /I b ) can be used to indicate the CO tolerance of the catalyst. [36][37][38][39] A low I f /I b value usually indicates poor oxidation of methanol to CO 2 during the forward anodic scan and excessive accumulation of residual carbon species (for example, CO) on the catalyst surface.…”

Section: Electrochemical Performancementioning

confidence: 99%

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A highly active, stable and synergistic Pt nanoparticles/Mo2C nanotube catalyst for methanol electro-oxidation

Zhang

Yang

et al. 2015

NPG Asia Mater

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Poor electrocatalytic activity and carbon monoxide (CO) poisoning of the anode in Pt-based catalysts are still two major challenges facing direct methanol fuel cells. Herein, we demonstrate a highly active and stable Pt nanoparticle/Mo 2 C nanotube catalyst for methanol electro-oxidation. Pt nanoparticles were deposited on Mo 2 C nanotubes using a controllable atomic layer deposition (ALD) technique. This catalyst showed much higher catalytic activity for methanol oxidation and superior CO tolerance, when compared with those of the conventional Pt/C and PtRu/C catalysts. The experimental evidence from X-ray absorption near-edge structure spectroscopy and scanning transmission X-ray microscopy clearly support a strong chemical interaction between the Pt nanoparticles and Mo 2 C nanotubes. Our studies show that the existence of Mo 2 C not only minimizes the required Pt usage but also significantly enhances CO tolerance and thus improves their durability. These results provide a promising strategy for the design of highly active next-generation catalysts.

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Graphene‐Based Materials as Nanocatalysts

Li¹,

Chen²

2013

Graphene Chemistry

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Single-atom Catalysis Using Pt/Graphene Achieved through Atomic Layer Deposition

Cited by 786 publications

References 34 publications

Influence of Carbon Support on Electronic Structure and Catalytic Activity of Pt Catalysts: Binding to the CO Molecule

Influence of Carbon Support on Electronic Structure and Catalytic Activity of Pt Catalysts: Binding to the CO Molecule

A highly active, stable and synergistic Pt nanoparticles/Mo2C nanotube catalyst for methanol electro-oxidation

Graphene‐Based Materials as Nanocatalysts

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