Chemical Bonding and Electronic Properties of the Co Adatom and Dimer Interacting with Polyaromatic Hydrocarbons

Mahmoodinia, Mehdi; Åstrand, Per‐Olof; Chen, De

doi:10.1021/acs.jpcc.5b07424

Cited by 9 publications

(13 citation statements)

References 176 publications

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“…This computational approach has been successful to describe the Pt/C and Co/C interactions. [16][17][18] The calculations were carried out using a polycyclic aromatic hydrocarbon (PAH) molecule as a representative example for modelling a real graphene material, since bonding to PAHs represents a model for binding to the π system relatively near defects in a real graphene material. Several PAH models were investigated in our previous work and the C 54 H 18 molecule was found to be a suitable model system.…”

Section: Computational Detailsmentioning

confidence: 99%

“…13,14 Interfaces between transition metals (TM) and graphene have been investigated extensively by several theoretical and experimental techniques. [16][17][18][19][20][21][22] Müller et al investigated a single Pt atom, Pt dimers and trimers on highly oriented pyrolytic graphite using a scanning tunneling microscope (STM) in air. 21 The Pt particles were produced by evaporation of platinum onto the surface and the position of the Pt atoms were stable, without changes for many scans.…”

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: Computational Detailsmentioning

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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“…Often, clusters of transition metals (TM) supported on appropriate surfaces are the active catalysts, and the understanding of the cluster-support interaction is of great scientific and technological interest. Also, for many other purposes, the presence of adsorbed clusters can modify the electronic and magnetic properties of the substrate system 1 . There are some challenges regarding the adsorption of molecular species on supported metal clusters, related to the coupling of the clusters with the substrate [2][3][4][5][6][7][8][9] .…”

Section: Introductionmentioning

confidence: 99%

Adsorption and growth of palladium clusters on graphdiyne

Seif

López

Granja-DelRío

et al. 2017

Phys. Chem. Chem. Phys.

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The density functional formalism has been used to investigate the stability and the properties of small palladium clusters supported on graphdiyne layers. The large triangular holes existing on the graphdiyne structure provide efficient sites to hold the clusters at small distances from the plane of the graphdiyne layer. The cluster adsorption energies, between 3 and 4 eV, are large enough to maintain the clusters tightly bound to the triangular holes. The competition between dispersion of Pd atoms on graphdiyne and growth of Pd clusters in the triangular holes of the layer is also discussed. In addition, the triangular holes can be simultaneously decorated with clusters on both sides. This indicates that palladium clusters could be used to build nanostructures formed by stacked graphdiyne layers with tailored interlayer distances controlled by the size of the clusters. The size of the clusters also controls the electronic HOMO-LUMO gap of the material.

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“…Another detection method less sensitive maybe based on the quenching of the magnetic moment of the Co2 clusters upon H2 adsorption. A recent DFT study showed that magnetic moment of two PAH-supported Co atoms is smaller than that of the end-on adsorbed dimer [27], therefore our calculations suggest that a sensor material based on Co2 rather than Co would be more sensitive. These rather technical aspects could become relevant for the design of functional conductive paramagnetic materials functionalised with Co2, which was recently shown to bind to graphene while preserving the magnetic properties of the cluster [46].…”

Section: Co2(h2)7mentioning

confidence: 62%

“…Magnetization measurements have shown considerable size-dependence of the magnetic moment in clusters with smaller clusters having higher magentic moments [26]. Therefore, the presence of high magnetic moments in small cobalt clusters such as Co2 and the possibility of funtionalising them to graphene sheets [27], makes them ideal for the development of novel materials for H-sensors or other megneto-electronic apllications in nanotechnology. There have been a few recent reports that have applied bimetallic [28] (e.g.…”

Section: Introductionmentioning

confidence: 99%

DFT study of the coverage-dependent chemisorption of molecular H 2 on neutral cobalt dimers

Zeinalipour-Yazdi

2017

Surface Science

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We have studied the coverage-dependent chemisorption of H2 on neutral cobalt dimers and found at θ < 0.4 the chemisorption is dissociative without a precursor-mediated physisorbed state and at 0.4 < θ < 1 it is both molecular and dissociative with a ratio of 6:1. During H2 chemisorption which is entirely side-on there is a very large quenching of the magnetic moment Δμ = 4.9 μB and a linear weakening of the metal-metal bond strength, given by calculated oscillator frequencies. An approximate equation is derived that can be implemented in kinetic models to take account of the coverage-dependent decrease of the adsorption energy of H2 on cobalt clusters. We show that sub-nanometer cobalt clusters when exposed to H2 have strong coverage-dependent properties useful for the development of very sensitive H2-trace gas sensors in the sub-ppm range.

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Chemical Bonding and Electronic Properties of the Co Adatom and Dimer Interacting with Polyaromatic Hydrocarbons

Cited by 9 publications

References 176 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

Adsorption and growth of palladium clusters on graphdiyne

DFT study of the coverage-dependent chemisorption of molecular H 2 on neutral cobalt dimers

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