Multifunctional chalcogenide (As2S3, As2Se3) dual-core PCF design for mid-IR optical communications

TL;DR

This paper designs and analyzes dual-core photonic crystal fibers made from chalcogenides for mid-infrared optical communications, demonstrating their birefringence, single-mode operation, and potential for polarization splitting and wavelength multiplexing.

Contribution

It introduces a novel multifunctional dual-core PCF design using chalcogenides for mid-IR applications, highlighting their birefringence and multiplexing capabilities.

Findings

Highly birefringent and single-moded in mid-IR range

Can operate as polarization splitters at 9 um

Suitable for integrated optics with low splice loss

Abstract

This work presents an integrated design of a multifunctional hexagonal lattice dual-core photonic crystal fiber (DC-PCF) with elliptical air-hole surrounding the cores, using two different chalcogenides (As2S3-Arsenic sulfide and As2Se3-Arsenic selenide) for mid-infrared (mid-IR) optical communications. Numerical study of both chalcogenide DC-PCF structures exhibits that the DC-PCFs are highly birefringent and single-moded in the mid-IR wavelength region (5 um to 13 um) of optical communications. Results show that both DC-PCFs can be operated as polarization splitters at 9 um wavelength for two orthogonal modes and they can also be used as WDM MUX-DeMUX for both X- and Y-polarization fundamental supermodes separating 9 um/10 um wavelengths (As2S3 DC-PCF) and 8 um/9 um wavelengths (As2Se3 DC-PCF). Moreover, the proposed chalcogenide DC-PCFs, with much lower splice loss at 8-10 um wavelength region, are appropriate enough for the practical applications in integrated optics and photonics.