Oxygen Switching of the Epitaxial Graphene–Metal Interaction

Larciprete, R.; Ulstrup, Søren; Lacovig, Paolo; Dalmiglio, Matteo; Bianchi, Marco; Mazzola, Federico; Hornekær, Liv; Orlando, Fabrizio; Baraldi, Alessandro; Hofmann, Philip; Lizzit, Silvano

doi:10.1021/nn302729j

Cited by 206 publications

(282 citation statements)

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“…After Gr growth, the Gr-alloy interface was exposed to a high flux of molecular oxygen (pressure ¼ 3 Â 10 À 3 torr) at 520 K. Following this procedure, it is possible to intercalate oxygen underneath the Gr layer and to selectively oxidize only the Al atoms at the metal interface. In fact, the intercalation of noble or light atoms has already proven to be an effective method to create an interface nanosheet between Gr and the substrate [21][22][23][24] . Figure 3a,b shows a set of high-resolution photoemission spectra acquired after different oxygen exposures, for the C1s and Al2p levels, respectively.…”

Section: Resultsmentioning

confidence: 99%

“…It is important to underline the absence of any interfacial buffer layer between Gr and alumina, which would give rise to a feature at 281.5 eV (the BE corresponding to the Al-C bonds) and 282.5 eV (Al-O-C bond) 28,29 and also to C-O bonds characteristic of epoxy, ethers, quinones and lactones, which typically show up in the C1s spectrum at binding energies4284.2 eV (ref. 22). In addition, we can safely rule out the formation of a high density of Gr defects such as single-and double-vacancies or Stone-Wales defects.…”

Section: Resultsmentioning

confidence: 99%

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Bottom-up approach for the low-cost synthesis of graphene-alumina nanosheet interfaces using bimetallic alloys

et al. 2014

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The production of high-quality graphene-oxide interfaces is normally achieved by graphene growth via chemical vapour deposition on a metallic surface, followed by transfer of the C layer onto the oxide, by atomic layer and physical vapour deposition of the oxide on graphene or by carbon deposition on top of oxide surfaces. These methods, however, come with a series of issues: they are complex, costly and can easily result in damage to the carbon network, with detrimental effects on the carrier mobility. Here we show that the growth of a graphene layer on a bimetallic Ni 3 Al alloy and its subsequent exposure to oxygen at 520 K result in the formation of a 1.5 nm thick alumina nanosheet underneath graphene. This new, simple and low-cost strategy based on the use of alloys opens a promising route to the direct synthesis of a wide range of interfaces formed by graphene and high-k dielectrics.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Bottom-up approach for the low-cost synthesis of graphene-alumina nanosheet interfaces using bimetallic alloys

et al. 2014

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“…First of all, in Ref. [37] authors showed that intercalation of oxygen leads to decoupling of graphene from the substrate with the shift of the Dirac point by 0.57 eV above the Fermi level. On the other hand, Cu intercalated graphene on Ir(111) is characterized by a gap between the π and π * states, opened by lifting the sublattice symmetry due to hybridization of the Cu and graphene bands [38].…”

Section: Discussionmentioning

confidence: 99%

Variation of the character of spin-orbit interaction by Pt intercalation underneath graphene on Ir(111)

et al. 2015

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The modification of the graphene spin structure is of interest for novel possibilities of application of graphene in spintronics. The most exciting of them demand not only high value of spin-orbit splitting of the graphene states, but non-Rashba behavior of the splitting and spatial modulation of the spin-orbit interaction. In this work we study the spin and electronic structure of graphene on Ir(111) with intercalated Pt monolayer. Pt interlayer does not change the 9.3 × 9.3 superlattice of graphene, while the spin structure of the Dirac cone becomes modified. It is shown that the Rashba splitting of the π state is reduced, while hybridization of the graphene and substrate states leads to a spin-dependent avoided-crossing effect near the Fermi level. Such a variation of spin-orbit interaction combined with the superlattice effects can induce a topological phase in graphene.

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“…27,[32][33][34] The intercalated oxygen atoms directly attack carbon atoms inside graphene islands with high oxidation rate. 27 On graphene/Ir(111) surfaces oxygen intercalation is also feasible in low pressure O 2 , 30,35 and the mechanism of direct attack by the intercalated oxygen atoms is active for the graphene oxidation. Moreover, wrinkles are present at the graphene/Ir(111) surfaces, 14,15 which probably make the oxygen intercalation easier and enhance the oxidation as well.…”

mentioning

confidence: 99%

Enhanced reactivity of graphene wrinkles and their function as nanosized gas inlets for reactions under graphene

Zhang

Cui

et al. 2013

Phys. Chem. Chem. Phys.

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Formation of wrinkles at graphene/Pt(111) surface was investigated by low energy electron microscopy (LEEM). Reversible wrinkling and unwrinkling of graphene sheets were observed upon cycled heating and cooling treatments, exhibiting a hysteresis effect with the temperature. In situ LEEM studies of graphene oxidation show preferential oxidation of the wrinkles than flat graphene sheets and graphene edges. The function of the wrinkles as one-dimensional (1D) nanosized gas inlets for oxygen and the strain at the distorted sp 2 -hybridized carbon atoms of the wrinkle sites can be attributed to the enhanced reactivity of wrinkles to the oxidation. Meanwhile, wrinkles also served as nanosized gas inlets for oxidation of CO intercalated between graphene and Pt(111). Considering that wrinkles are frequently present in graphene structures, the role of wrinkles as 1D reaction channels and their enhanced reactivity to reactions may have an important effect on graphene chemistry.

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Oxygen Switching of the Epitaxial Graphene–Metal Interaction

Cited by 206 publications

References 50 publications

Bottom-up approach for the low-cost synthesis of graphene-alumina nanosheet interfaces using bimetallic alloys

Bottom-up approach for the low-cost synthesis of graphene-alumina nanosheet interfaces using bimetallic alloys

Variation of the character of spin-orbit interaction by Pt intercalation underneath graphene on Ir(111)

Enhanced reactivity of graphene wrinkles and their function as nanosized gas inlets for reactions under graphene

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