Formation and Structure of Graphene Waves on Fe(110)

Nikolay Vinogradov; Alexei Zakharov; V. Kocevski; J. Rusz; K. A. Simonov; O. Eriksson; Anders Mikkelsen; Edvin Lundgren; A. S. Vinogradov; Nils Mårtensson; Alexei Preobrajenski

doi:10.1103/PhysRevLett.109.026101

Formation and Structure of Graphene Waves on Fe(110)

Nikolay Vinogradov, Alexei Zakharov, V. Kocevski, J. Rusz, K. A. Simonov, O. Eriksson, Anders Mikkelsen, Edvin Lundgren, A. S. Vinogradov, Nils Mårtensson, Alexei Preobrajenski

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Abstract

A very rich Fe-C phase diagram makes the formation of graphene on iron surfaces a challenging task. Here we demonstrate that the growth of graphene on epitaxial iron films can be realized by chemical vapor deposition at relatively low temperatures, and that the formation of carbides can be avoided in excess of the carbon-containing precursors. The resulting graphene monolayer creates a novel periodically corrugated pattern on Fe(110). Using low-energy electron microscopy and scanning tunneling microscopy, we show that it is modulated in one dimension forming long waves with a period of similar to 4 nm parallel to the [001] direction of the substrate, with an additional height modulation along the wave crests. The observed topography of the graphene/Fe superstructure is well reproduced by density functional theory calculations, and found to result from a unique combination of the lattice mismatch and strong interfacial interaction, as probed by core-level photoemission and x-ray absorption spectroscopy.

Original language	English
Article number	026101
Journal	Physical Review Letters
Volume	109
Issue number	2
DOIs	https://doi.org/10.1103/PhysRevLett.109.026101
Publication status	Published - 2012

Subject classification (UKÄ)

Natural Sciences
Physical Sciences
Atom and Molecular Physics and Optics

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10.1103/PhysRevLett.109.026101

Vinogradov2012a

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title = "Formation and Structure of Graphene Waves on Fe(110)",

abstract = "A very rich Fe-C phase diagram makes the formation of graphene on iron surfaces a challenging task. Here we demonstrate that the growth of graphene on epitaxial iron films can be realized by chemical vapor deposition at relatively low temperatures, and that the formation of carbides can be avoided in excess of the carbon-containing precursors. The resulting graphene monolayer creates a novel periodically corrugated pattern on Fe(110). Using low-energy electron microscopy and scanning tunneling microscopy, we show that it is modulated in one dimension forming long waves with a period of similar to 4 nm parallel to the [001] direction of the substrate, with an additional height modulation along the wave crests. The observed topography of the graphene/Fe superstructure is well reproduced by density functional theory calculations, and found to result from a unique combination of the lattice mismatch and strong interfacial interaction, as probed by core-level photoemission and x-ray absorption spectroscopy.",

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T1 - Formation and Structure of Graphene Waves on Fe(110)

AU - Vinogradov, Nikolay

AU - Zakharov, Alexei

AU - Kocevski, V.

AU - Rusz, J.

AU - Simonov, K. A.

AU - Eriksson, O.

AU - Mikkelsen, Anders

AU - Lundgren, Edvin

AU - Vinogradov, A. S.

AU - Mårtensson, Nils

AU - Preobrajenski, Alexei

PY - 2012

Y1 - 2012

N2 - A very rich Fe-C phase diagram makes the formation of graphene on iron surfaces a challenging task. Here we demonstrate that the growth of graphene on epitaxial iron films can be realized by chemical vapor deposition at relatively low temperatures, and that the formation of carbides can be avoided in excess of the carbon-containing precursors. The resulting graphene monolayer creates a novel periodically corrugated pattern on Fe(110). Using low-energy electron microscopy and scanning tunneling microscopy, we show that it is modulated in one dimension forming long waves with a period of similar to 4 nm parallel to the [001] direction of the substrate, with an additional height modulation along the wave crests. The observed topography of the graphene/Fe superstructure is well reproduced by density functional theory calculations, and found to result from a unique combination of the lattice mismatch and strong interfacial interaction, as probed by core-level photoemission and x-ray absorption spectroscopy.

AB - A very rich Fe-C phase diagram makes the formation of graphene on iron surfaces a challenging task. Here we demonstrate that the growth of graphene on epitaxial iron films can be realized by chemical vapor deposition at relatively low temperatures, and that the formation of carbides can be avoided in excess of the carbon-containing precursors. The resulting graphene monolayer creates a novel periodically corrugated pattern on Fe(110). Using low-energy electron microscopy and scanning tunneling microscopy, we show that it is modulated in one dimension forming long waves with a period of similar to 4 nm parallel to the [001] direction of the substrate, with an additional height modulation along the wave crests. The observed topography of the graphene/Fe superstructure is well reproduced by density functional theory calculations, and found to result from a unique combination of the lattice mismatch and strong interfacial interaction, as probed by core-level photoemission and x-ray absorption spectroscopy.

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U2 - 10.1103/PhysRevLett.109.026101

DO - 10.1103/PhysRevLett.109.026101

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SN - 1079-7114

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JO - Physical Review Letters

JF - Physical Review Letters

IS - 2

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ER -

Formation and Structure of Graphene Waves on Fe(110)

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