Title :
A Graphene-Enhanced Fiber-Optic Phase Modulator With Large Linear Dynamic Range
Author :
Feng Zhou ; Ran Hao ; Xiao-Feng Jin ; Xian-Min Zhang ; Er-Ping Li
Author_Institution :
Dept. of Inf. Sci. & Electron. Eng., Zhejiang Univ., Hangzhou, China
Abstract :
We propose a graphene-based modulator integrated into currently used communication fibers. The graphene is directly built into the core of the fiber to ensure the coupling efficiency. The fiber is deliberately side-polished to enhance the light-graphene interaction. The two-dimensional model analysis method and three-dimensional finite difference time domain method are used to rigorously disclose the light modulation mechanism under the anisotropic graphene modeling, which is merely conducted in previous studies. Based on such a structure, a phase modulator with an arm length of 127 μm is numerically demonstrated with enhanced modulation efficiency. A quasi-linear relation between the phase change and chemical potential of graphene is found theoretically for the first time, providing a large linear dynamic range to control the phase of optical modulation.
Keywords :
chemical potential; finite difference time-domain analysis; graphene; integrated optoelectronics; optical communication equipment; optical fibre communication; optical fibres; optical modulation; phase modulation; C; anisotropic graphene modeling; arm length; chemical potential; communication fibers; coupling efficiency; graphene-enhanced fiber-optic phase modulator; light modulation mechanism; light-graphene interaction; linear dynamic range; modulation efficiency; phase change; quasilinear relation; side-polishing; three-dimensional finite difference time domain method; two-dimensional model analysis; Chemicals; Graphene; Modulation; Optical fiber communication; Optical fiber devices; Optical fibers; Graphene; fiber modulator; light-matter interaction; phase modulation;
Journal_Title :
Photonics Technology Letters, IEEE
DOI :
10.1109/LPT.2014.2336660
