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Tailoring of electromagnetic field localizations by two-dimensional graphene nanostructures.


ABSTRACT: Graphene has great potential for enhancing light-matter interactions in a two-dimensional regime due to surface plasmons with low loss and strong light confinement. Further utilization of graphene in nanophotonics relies on the precise control of light localization properties. Here, we demonstrate the tailoring of electromagnetic field localizations in the mid-infrared region by precisely shaping the graphene into nanostructures with different geometries. We generalize the phenomenological cavity model and employ nanoimaging techniques to quantitatively calculate and experimentally visualize the two-dimensional electromagnetic field distributions within the nanostructures, which indicate that the electromagnetic field can be shaped into specific patterns depending on the shapes and sizes of the nanostructures. Furthermore, we show that the light localization performance can be further improved by reducing the sizes of the nanostructures, where a lateral confinement of ?0/180 of the incidence light can be achieved. The electromagnetic field localizations within a nanostructure with a specific geometry can also be modulated by chemical doping. Our strategies can, in principle, be generalized to other two-dimensional materials, therefore providing new degrees of freedom for designing nanophotonic components capable of tailoring two-dimensional light confinement over a broad wavelength range.

SUBMITTER: Zheng ZB 

PROVIDER: S-EPMC6061900 | biostudies-other | 2017 Oct

REPOSITORIES: biostudies-other

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Tailoring of electromagnetic field localizations by two-dimensional graphene nanostructures.

Zheng Ze-Bo ZB   Li Jun-Tao JT   Ma Teng T   Fang Han-Lin HL   Ren Wen-Cai WC   Chen Jun J   She Jun-Cong JC   Zhang Yu Y   Liu Fei F   Chen Huan-Jun HJ   Deng Shao-Zhi SZ   Xu Ning-Sheng NS  

Light, science & applications 20171006 10


Graphene has great potential for enhancing light-matter interactions in a two-dimensional regime due to surface plasmons with low loss and strong light confinement. Further utilization of graphene in nanophotonics relies on the precise control of light localization properties. Here, we demonstrate the tailoring of electromagnetic field localizations in the mid-infrared region by precisely shaping the graphene into nanostructures with different geometries. We generalize the phenomenological cavit  ...[more]

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