Electrically defined topological interface states of graphene surface plasmons based on a gate-tunable quantum Bragg grating

Fan, Zhiyuan and Gupta, Shourya Dutta and Gladstone, Ran and et al, . (2019) Electrically defined topological interface states of graphene surface plasmons based on a gate-tunable quantum Bragg grating. Nanophotonics, 8 (8). pp. 1417-1431. ISSN 2192-8614

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Abstract

A periodic metagate is designed on top of a boron nitride-graphene heterostructure to modulate the local carrier density distribution on the monolayer graphene. This causes the bandgaps of graphene surface plasmon polaritons to emerge because of either the interaction between the plasmon modes, which are mediated by the varying local carrier densities, or their interaction with the metal gates. Using the example of a double-gate graphene device, we discuss the tunable band properties of graphene plasmons due to the competition between these two mechanisms. Because of this, a bandgap inversion, which results in a Zak phase switching, can be realized through electrostatic gating. Here we also show that an anisotropic plasmonic topological edge state exists at the interface between two graphene gratings of different Zak phases. While the orientation of the dipole moments can differentiate the band topologies of each graphene grating, the angle of radiation remains a tunable property. This may serve as a stepping stone toward active control of the band structures of surface plasmons for potential applications in optical communication, wave steering, or sensing.

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IITH Creators:
IITH CreatorsORCiD
Gupta, Shourya DuttaUNSPECIFIED
Item Type: Article
Uncontrolled Keywords: active metasurface,band topology,graphene plasmons,topological interface state,Indexed in Scopus and WoS
Subjects: Materials Engineering > Materials engineering
Divisions: Department of Material Science Engineering
Depositing User: Library Staff
Date Deposited: 29 Oct 2019 09:50
Last Modified: 29 Oct 2019 10:05
URI: http://raiithold.iith.ac.in/id/eprint/6886
Publisher URL: http://doi.org/10.1515/nanoph-2019-0108
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