# High reflection from a one-dimensional array of graphene nanoribbons

**Authors:** Nathan Zhao, Zhexin Zhao, Ian Williamson, Salim Boutami, Bo Zhao,, Shanhui Fan

arXiv: 1812.04768 · 2018-12-13

## TL;DR

This paper demonstrates that a one-dimensional array of graphene nanoribbons can achieve up to 90% reflectivity through guided plasmonic resonances, with no intrinsic limit on radiative decay rate even at atomic thickness.

## Contribution

It introduces a theoretical framework showing no intrinsic limit on radiative decay rate in atomic-scale systems and designs for high reflectivity in atomically-thin graphene layers.

## Key findings

- Achieves up to 90% reflectivity with graphene nanoribbons.
- No intrinsic limit on radiative decay rate at atomic thickness.
- Designs for high external radiative rate in plasmonic resonances.

## Abstract

We show that up to 90% reflectivity can be achieved by using guided plasmonic resonances in a one-dimensional periodic array of plasmonic nanoribbon. In general, to achieve strong reflection from a guided resonance system requires one to operate in the strongly over-coupled regime where the radiative decay rate dominates over the intrinsic loss rate of the resonances. Using an argument similar to what has been previous used to derive the Chu-Harrington limit for antennas, we show theoretically that there is no intrinsic limit for the radiative decay rate even when the system has an atomic scale thickness, in contrast to the existence of such limits on antennas. We also show that the current distribution due to plasmonic resonance can be designed to achieve very high external radiative rate. Our results show that high reflectivity can be achieved in an atomically-thin graphene layer, pointing to a new opportunity for creating atomically-thin optical devices.

## Full text

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## Figures

5 figures with captions in the complete paper: https://tomesphere.com/paper/1812.04768/full.md

## References

33 references — full list in the complete paper: https://tomesphere.com/paper/1812.04768/full.md

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Source: https://tomesphere.com/paper/1812.04768