Litcius/Paper detail

Highly Dispersive Optical Fiber for Orbital Angular Momentum Modes

Wenpu Geng, Yuxi Fang, Yingning Wang, Changjing Bao, Hao Zhang, Yongxiong Ren, Zhongqi Pan, Yang Yue

2022Journal of Lightwave Technology10 citationsDOI

Abstract

Orbital angular momentum (OAM) modes, featured by the unique properties of the helical phase front and annular intensity profile, have shown enormous potential for a wide range of applications. Optical fibers with ring-shape profile have been experimentally proven for supporting stable OAM beam propagation. In most instances, managing the chromatic dispersion is of vital importance in a variety of optical fiber systems. In this paper, we summarize optical fibers with concentric ring cores for extremely dispersive OAM modes. The properties of the OAM mode in double ring-core fiber are presented, including the effective refractive index, effective mode area, power integral ratio, chromatic dispersion, and loss. Photonic crystal fiber and triple ring-core fiber, which share the same operation principle for dispersive OAM modes as the one in the dual-ring fiber, are also briefly introduced.

Topics & Concepts

OpticsPhotonic-crystal fiberGraded-index fiberAngular momentumOptical fiberCore (optical fiber)Double-clad fiberDispersion (optics)Single-mode optical fiberMode volumeDispersion-shifted fiberOrbital angular momentum of lightZero-dispersion wavelengthFiberPolarization-maintaining optical fiberMaterials sciencePhysicsFiber optic sensorTotal angular momentum quantum numberQuantum mechanicsComposite materialOrbital Angular Momentum in OpticsPhotonic Crystal and Fiber OpticsOptical Coherence Tomography Applications