Graphene on nickel (100) micrograins: Modulating the interface interaction by extended moiré superstructures

Zou, Zhiyu; Carnevali, Virginia; Jugovac, Matteo; Patera, Laerte L.; Sala, Alessandro; Panighel, Mirco; Cepek, Cinzia; Soldano, Germán; Mariscal, Marcelo M.; Peressi, Maria; Comelli, Giovanni; Africh, Cristina

doi:10.1016/j.carbon.2018.01.010

Cited by 32 publications

(81 citation statements)

References 46 publications

(61 reference statements)

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“…The (100) facet of the Ni-poly substrate is found to be featured with flat terraces as wide as tens of nanometers, separated by step bunches which can span up to tens of atomic layers. [15] It should be noted that with the growth conditions adopted in this work (see Methods), graphene is always monolayer, as recently found also on Ni(100) thin films via ambient-pressure CVD preparation; [29] moreover, like the case of Ni(111) single crystals, graphene never grows rightly above nickel carbide, at variance with the behavior observed on early transition metals. [31][32] Similarly to what already reported for the Ni(111) single crystal, [11] two graphene growth mechanisms are active on flat (100) terraces of Ni-poly, corresponding to in-plane transformation and on-terrace adlayer growth, respectively, which will be 8 reported elsewhere.…”

Section: Joint Growth Mechanism Of Graphene Together With Monoatomic supporting

confidence: 56%

“…The same series of simple pre-treatments already described in our previous work [15] was used to prepare Ni-poly foils suitable for STM measurements. Here, we focus on grains exposing the (100) facet, one of the ubiquitous orientations in Ni-poly substrates.…”

Section: Joint Growth Mechanism Of Graphene Together With Monoatomic mentioning

confidence: 99%

“…Here, we focus on grains exposing the (100) facet, one of the ubiquitous orientations in Ni-poly substrates. [15,[26][27] The extended moiré pattern which originates on these facets from the interface symmetry mismatch can serve as a hallmark of graphene formation and a magnification of the defects in graphene lattice even at a relatively large scan scale. [15,[28][29][30] It should be noted that this experimental approach could be easily extended to differently oriented facets in Ni and even other polycrystalline transition metal foils, whenever graphene grows at a temperature and a hydrocarbon pressure compatible with the specifics of the microscope.…”

Section: Joint Growth Mechanism Of Graphene Together With Monoatomic mentioning

confidence: 99%

“…First of all we tried to clarify the origin of the previously described moiré pattern adopted by an infinite graphene layer on Ni(100). [15] To this purpose, we simulate a growing graphene flake with ribbons of different width in the growing [ ] direction and infinitely long along the moiré stripes parallel to the [011] direction ( Fig. 4c, see Fig.…”

Section: Dft Simulation Of Constant-width Terraces At Step Bunchesmentioning

confidence: 99%

“…[12][13][14] Recently, the feasibility of STM measurements has been proved also for graphene on polycrystalline nickel (Ni-poly), after suitable sample pretreatment. [15] Operando STM investigations of graphene growth on polycrystalline substrates appears therefore to be a viable route to clarify the atomistic details of the process.…”

Section: Introductionmentioning

confidence: 99%

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Operando atomic-scale study of graphene CVD growth at steps of polycrystalline nickel

Zou

Carnevali

Patera

et al. 2020

Carbon

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An operando investigation of graphene growth on (100) grains of polycrystalline nickel (Ni) surfaces was performed by means of variable-temperature scanning tunneling microscopy complemented by density functional theory simulations. A clear description of the atomistic mechanisms ruling the graphene expansion process at the stepped regions of the substrate is provided, showing that different routes can be followed, depending on the height of the steps to be crossed. When a growing graphene flake reaches a monoatomic step, it extends jointly with the underlying Ni layer; for higher Ni edges, a different process, involving step retraction and graphene landing, becomes active. At step bunches, the latter mechanism leads to a peculiar 'staircase formation' behavior, where terraces of equal width form under the overgrowing graphene, driven by a balance in the energy cost between C-Ni bond formation and stress accumulation in the carbon layer. Our results represent a step towards bridging the material gap in searching new strategies and methods for the optimization of chemical vapor deposition graphene production on polycrystalline metal surfaces.

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Section: Joint Growth Mechanism Of Graphene Together With Monoatomic supporting

confidence: 56%

Section: Joint Growth Mechanism Of Graphene Together With Monoatomic mentioning

confidence: 99%

Section: Joint Growth Mechanism Of Graphene Together With Monoatomic mentioning

confidence: 99%

Section: Dft Simulation Of Constant-width Terraces At Step Bunchesmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Operando atomic-scale study of graphene CVD growth at steps of polycrystalline nickel

Zou

Carnevali

Patera

et al. 2020

Carbon

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Quantum Confinement in Aligned Zigzag “Pseudo‐Ribbons” Embedded in Graphene on Ni(100)

Sala

Zou

Carnevali

et al. 2021

Adv Funct Materials

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Lateral quantum confinement is of great interest in tuning the electronic properties of graphene‐based nanostructures, making them suitable for technological applications. In principle, these properties might be controlled through the edge topology: for example, zigzag nanoribbons are predicted to have spin‐polarized edge states. The practical realization of these structures is of utmost importance in fully harnessing the electronic properties of graphene. Here, the formation of regular, 1.4 nm wide ribbon‐like graphene structures with zigzag edges are reported, showing 1D electronic states. It is found that these “pseudo‐ribbons” embedded in single‐layer graphene supported on Ni(100) can spontaneously form upon carbon segregation underneath 1D graphene moiré domains, extending hundreds of nanometers in length. On the basis of both microscopy/spectroscopy/diffraction experiments and theoretical simulations, it is shown that these structures, even though seamlessly incorporated in a matrix of strongly interacting graphene, exhibit electronic properties closely resembling those of zigzag nanoribbons.

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Exceptionally Stable Cobalt Nanoclusters on Functionalized Graphene

Chesnyak,

Stavrić,

Panighel

et al. 2024

Small Structures

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To improve reactivity and achieve a higher material efficiency, catalysts are often used in the form of clusters with nanometer dimensions, down to single atoms. Since the corresponding properties are highly structure‐dependent, a suitable support is thus required to ensure cluster stability during operating conditions. Herein, an efficient method to stabilize cobalt nanoclusters on graphene grown on nickel substrates, exploiting the anchoring effect of nickel atoms incorporated in the carbon network is presented. The anchored nanoclusters are studied by in situ variable temperature scanning tunneling microscopy at different temperatures and upon gas exposure. Cluster stability upon annealing up to 200 °C and upon CO exposure at least up to 1 × 10−6 mbar CO partial pressure is demonstrated. Moreover, the dimensions of the cobalt nanoclusters remain surprisingly small (<3 nm diameter) with a narrow size distribution. Density functional theory calculations demonstrate that the interplay between the low diffusion barrier on graphene on nickel and the strong anchoring effect of the nickel atoms leads to the increased stability and size selectivity of these clusters. This anchoring technique is expected to be applicable also to other cases, with clear advantages for transition metals that are usually difficult to stabilize.

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Graphene on nickel (100) micrograins: Modulating the interface interaction by extended moiré superstructures

Cited by 32 publications

References 46 publications

Operando atomic-scale study of graphene CVD growth at steps of polycrystalline nickel

Operando atomic-scale study of graphene CVD growth at steps of polycrystalline nickel

Quantum Confinement in Aligned Zigzag “Pseudo‐Ribbons” Embedded in Graphene on Ni(100)

Exceptionally Stable Cobalt Nanoclusters on Functionalized Graphene

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