Giant Faraday rotation in single- and multilayer graphene

The rotation of polarized light in certain materials when subject to a magnetic field is known as the Faraday effect. Remarkably, just one atomic layer of graphene exhibits Faraday rotations that would only be measurable in other materials many hundreds of micrometres thick. The rotation of the pola...

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Vydáno v:Nature physics Ročník 7; číslo 1; s. 48 - 51
Hlavní autoři: Crassee, Iris, Levallois, Julien, Walter, Andrew L., Ostler, Markus, Bostwick, Aaron, Rotenberg, Eli, Seyller, Thomas, van der Marel, Dirk, Kuzmenko, Alexey B.
Médium: Journal Article
Jazyk:angličtina
Vydáno: London Nature Publishing Group UK 01.01.2011
Nature Publishing Group
Témata:
Atomic
Atomic structure
Classical and Continuum Physics
Complex Systems
Condensed Matter Physics
Crystals
Cyclotron resonance
Gases
Graphene
Infrared
letter
Magnetic fields
Mathematical and Computational Physics
Molecular
Multilayers
Optical and Plasma Physics
Physics
Physics and Astronomy
Polarization
Theoretical
Two dimensional
ISSN:1745-2473, 1745-2481
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Popis
Shrnutí:The rotation of polarized light in certain materials when subject to a magnetic field is known as the Faraday effect. Remarkably, just one atomic layer of graphene exhibits Faraday rotations that would only be measurable in other materials many hundreds of micrometres thick. The rotation of the polarization of light after passing a medium in a magnetic field, discovered by Faraday 1 , is an optical analogue of the Hall effect, which combines sensitivity to the carrier type with access to a broad energy range. Up to now the thinnest structures showing the Faraday rotation were several-nanometre-thick two-dimensional electron gases 2 . As the rotation angle is proportional to the distance travelled by the light, an intriguing issue is the scale of this effect in two-dimensional atomic crystals or films—the ultimately thin objects in condensed matter physics. Here we demonstrate that a single atomic layer of carbon—graphene—turns the polarization by several degrees in modest magnetic fields. Such a strong rotation is due to the resonances originating from the cyclotron effect in the classical regime and the inter-Landau-level transitions in the quantum regime. Combined with the possibility of ambipolar doping 3 , this opens pathways to use graphene in fast tunable ultrathin infrared magneto-optical devices.
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ISSN:1745-2473
1745-2481
DOI:10.1038/nphys1816