Back to Search Start Over

Optical tunable multifunctional slow light device based on double monolayer graphene grating-like metamaterial

Authors :
Zhihui He
Yulan Dong
Xuelei Li
Zhiquan Chen
Xiaojing Wang
Guozheng Nie
Hui Xu
Longhui He
Source :
New Journal of Physics. 23:123025
Publication Year :
2021
Publisher :
IOP Publishing, 2021.

Abstract

A very simple optical tunable device, which can realize multiple functions of frequency selection, reflection and slow light, is presented at the investigation. The proposed device is constructed by a periodic grating-like structure. There are two dielectrics (graphene and silicon) in a period of the equivalent grating. The incident light will strongly resonate with the graphene of electrostatic doping, forming an evanescent wave propagating along the surface of graphene, and this phenomenon is the surface plasmon. Under constructive interference of the polaritons, a unique plasmonic induced transparency phenomenon will be achieved. The induced transparency produced by this device can be well theoretically fitted by the bright and dark mode of optical equivalent cavity which can be called coupled mode theory. This theory can well analyze the influence of various modes and various losses between the function of this device. The device can use gate voltages for electrostatic doping in order to change the graphene carrier concentration and tune the optical performance of the device. Moreover, the length of the device in y-direction is will be much larger than the length of single cycle, providing some basis for realizing the fast tunable function and laying a foundation for the integration. Through a simulation and calculation, we can find that the group index and group delay of this device are as high as 515 and 0.257 picoseconds (ps) respectively, so it can provide a good construction idea for the slow light device. The proposed grating-like metamaterial structure can provide certain simulation and theoretical help for the optical tunable reflectors, absorbers, and slow light devices.

Details

ISSN :
13672630
Volume :
23
Database :
OpenAIRE
Journal :
New Journal of Physics
Accession number :
edsair.doi...........fd2b0ec7f2c1d1cc1cf33eda149b91bc
Full Text :
https://doi.org/10.1088/1367-2630/ac3d50