Spin–Orbit Coupling Induced Gap in Graphene on Pt(111) with Intercalated Pb Monolayer

Климовских, И. И.; Otrokov, M. M.; Voroshnin, Vladimir; Sostina, Daria; Petaccia, L.; Santo, Giovanni Di; Thakur, Sangeeta; Chulkov, Evgueni V.; Shikin, A. M.

doi:10.1021/acsnano.6b05982

Cited by 94 publications

(115 citation statements)

References 38 publications

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“…5c). This is the first time that the band dispersion in the valence band of graphene patches orientated with the main directions of the Pt(111) crystal has been measured, instead of the ARPES more usually reported, which pertains to the superstructure rotated by 30° [44,51,52,53] The full wave-vector ARPES data clearly prove the presence of graphene oriented with h-BN on a large scale, which occurs due to a 2D heteroepitaxial growth favoured by the h-BN edges [25,54].…”

Section: Resultsmentioning

confidence: 74%

Microscopic insight into the single step growth of in-plane heterostructures between graphene and hexagonal boron nitride

et al. 2019

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S. (2019). Microscopic insight into the single step growth of in-plane heterostructures between graphene and hexagonal boron nitride. Nano Research, 12(3), 675-682. https://doi. Close, Bristol BS8 1TS (UK) . A variety of h-BN/graphene nanostructures can be obtained by the controlled decomposition of dimethylamino borane complex on the Pt (111) surface at different temperatures, which encompass B and N doped graphene layers, h-BN/Graphene 2D Janus quantum dots, and h-BN/graphene patchy layers. For the first time we report a quite unique 2D heterostructure where the graphene armchair edges are seamlessly connected to the h-BN zigzag edges. ABSTRACTGraphene-h-BN hybrid nanostructures are grown in one step on the Pt(111) surface by ultra-high vacuum chemical vapor deposition using a single precursor, the dimethylamino borane complex. By varying the deposition conditions, different nanostructures ranging from a fully continuous hybrid monolayer to well-separated Janus nanodots can be obtained. The growth starts with heterogeneous nucleation on morphological defects such as Pt step edges and proceeds by the addition of small clusters formed by the decomposition of the dimethylamino borane complex. Scanning tunneling microscopy measurements indicate that a sharp zigzag in-plane boundary is formed when graphene grows aligned with the Pt substrate and consequently with the h-BN layer as well. When graphene grows rotated by 30°, the graphene armchair edges are seamlessly connected to h-BN zigzag edges. This is confirmed by a thorough density functional theory (DFT) study. Angle Resolved Photoemission Spectroscopy data suggests that both h-BN and graphene present the typical electronic structure of self-standing noninteracting materials

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Section: Resultsmentioning

confidence: 74%

Microscopic insight into the single step growth of in-plane heterostructures between graphene and hexagonal boron nitride

et al. 2019

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“…The first case should induce changes mainly in the G's properties already perturbed by the metal surface, while the latter might significantly alter the graphene-substrate proximity, as graphene will now interact with the metal mainly via the intercalated adatom. Importantly, both decoration and intercalation can be realized experimentally [12][13][14][15][16][17][18][19][20][21][22][23] and are known to provide several interesting options for engineering of graphene's properties, in addition to any possible enhancement of SOC [24]. Here, we will focus on two previously studied models, G/Pt(111) and G/Au/Ni(111) which present markedly different electronic and magnetic properties, and consider the adsorption of one species for each system, namely, a Pt adatom for G/Pt(111) and an Au adatom for G/Au/Ni(111).…”

Section: Introductionmentioning

confidence: 99%

Spin–orbit proximity effect in graphene on metallic substrates: decoration versus intercalation with metal adatoms

Sławińska

Cerdá

2019

New J. Phys.

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The so-called spin-orbit proximity effect experimentally realized in graphene (G) on several different heavy metal surfaces opens a new perspective to engineer the spin-orbit coupling for new generation spintronics devices. Here, via large-scale density functional theory calculations performed for two distinct graphene/metal models, G/Pt(111) and G/Au/Ni (111), we show that the spin-orbit splitting of the Dirac cones (DCs) in these structures might be enhanced by either adsorption of adatoms on top of graphene (decoration) or between the graphene and the metal (intercalation). While the decoration by inducing strong graphene-adatom interaction suppresses the linearity of the G's π bands, the intercalated structures reveal a weaker adatom-mediated graphene/substrate hybridization which preserves well-defined although broadened DCs. Remarkably, the intercalated G/Pt(111) structure exhibits splittings considerably larger than the defect-free case.

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“…It has even been shown that the stepwise intercalation of silicon and oxygen can lead to silicon oxide formation under epitaxial graphene, electrically isolating the graphene from the highly conductive substrate on which it is grown [27], and re-establishing the innate properties of the graphene. Further effects of intercalation can be the generation of substantial electron or hole doping densities [24,[28][29][30], an increase in the intrinsically very weak spin-orbit interaction [31,32] and the induction of superconductivity [33]. Given this ability to bestow graphene with new properties and to suppress the graphene-substrate interaction by intercalation, it is tempting to assume that epitaxially grown SL TMDCs could equally profit from such an approach.…”

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confidence: 99%

Quasi-free-standing single-layer WS2 achieved by intercalation

Mahatha

Dendzik

Sanders

et al. 2018

Phys. Rev. Materials

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Large-area and high-quality single-layer transition metal dichalcogenides can be synthesized by epitaxial growth on single-crystal substrates. An important advantage of this approach is that the interaction between the single-layer and the substrate can be strong enough to enforce a single crystalline orientation of the layer. On the other hand, the same interaction can lead to hybridization effects, resulting in the deterioration of the single-layer's native properties. This dilemma can potentially be solved by decoupling the single-layer from the substrate surface after the growth via intercalation of atoms or molecules. Here we show that such a decoupling can indeed be achieved for single-layer WS2 epitaxially grown on Ag(111) by intercalation of Bi atoms. This process leads to a suppression of the single-layer WS2-Ag substrate interaction, yielding an electronic band structure reminiscent of free-standing single-layer WS2. arXiv:1811.05748v1 [cond-mat.mtrl-sci]

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Spin–Orbit Coupling Induced Gap in Graphene on Pt(111) with Intercalated Pb Monolayer

Cited by 94 publications

References 38 publications

Microscopic insight into the single step growth of in-plane heterostructures between graphene and hexagonal boron nitride

Microscopic insight into the single step growth of in-plane heterostructures between graphene and hexagonal boron nitride

Spin–orbit proximity effect in graphene on metallic substrates: decoration versus intercalation with metal adatoms

Quasi-free-standing single-layer WS2 achieved by intercalation

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