Symmetry enhanced non-reciprocal polarization rotation in a terahertz metal-graphene metasurface

In the present article we numerically investigated the magneto-optical behaviour of a sub-wavelength structure composed by a monolayer graphene and a metallic metasurface of optical resonators. Using this hybrid graphene-metal structure, a large increase of the non-reciprocal polarization rotation o...

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Veröffentlicht in:Optics express 2018-02, Vol.26 (3), p.3328-3340
Hauptverfasser: Ottomaniello, Andrea, Zanotto, Simone, Baldacci, Lorenzo, Pitanti, Alessandro, Bianco, Federica, Tredicucci, Alessandro
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Sprache:eng
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Zusammenfassung:In the present article we numerically investigated the magneto-optical behaviour of a sub-wavelength structure composed by a monolayer graphene and a metallic metasurface of optical resonators. Using this hybrid graphene-metal structure, a large increase of the non-reciprocal polarization rotation of graphene can be achieved over a broad range of terahertz frequencies. We demonstrate that the symmetry of the resonator geometry plays a key role for the performance of the system: in particular, increasing the symmetry of the resonator the non-reciprocal properties can be progressively enhanced. Moreover, the possibility to exploit the metallic metasurface as a voltage gate to vary the graphene Fermi energy allows the system working point to be tuned to the desired frequency range. Another peculiar result is the achievement of a structure able to operate both in transmission and reflection with almost the same performance, but in a different frequency range of operation. The described system is hence a sub-wavelength, tunable, multifunctional, effective non-reciprocal element in the terahertz region.
ISSN:1094-4087
1094-4087
DOI:10.1364/OE.26.003328