Near-elliptic core triangular-lattice and square-lattice PCFs: a comparison of birefringence, cut-off and GVD characteristics towards fiber device application

TL;DR

This paper compares near-elliptic core triangular- and square-lattice photonic crystal fibers in terms of birefringence, dispersion, and effective area, providing insights for optimizing fiber design for specific applications like supercontinuum generation.

Contribution

It offers a detailed numerical comparison of two PCF types, highlighting their distinct properties and suitability for various fiber device applications.

Findings

Triangular-lattice PCFs exhibit higher birefringence.

Square-lattice PCFs support wider single-mode operation.

Square-lattice PCFs are advantageous for mid-IR supercontinuum generation.

Abstract

In this work, detailed numerical analysis of the near-elliptic core index-guiding triangular-lattice and square-lattice photonic crystal fiber (PCFs) are reported for birefringence, single mode, cut-off behavior, group velocity dispersion and effective area properties. For the same relative values of d/P, triangular-lattice PCFs show higher birefringence whereas the square-lattice PCFs show a wider range of single-mode operation. Square-lattice PCF was found to be endlessly single-mode for higher air-filling fraction (d/P). Smaller lengths of triangular-lattice PCF are required for dispersion compensation whereas PCFs with square-lattice with nearer relative dispersion slope (RDS) can better compensate the broadband dispersion. Square-lattice PCFs show ZDW red-shifted, making it preferable for mid-IR supercontinuum generation (SCG) with highly non-linear chalcogenide material. Square-lattice PCFs show higher dispersion slope that leads to compression of the broadband, thus accumulating more power in the pulse. On the other hand, triangular-lattice PCF with flat dispersion profile can generate broader SCG. Square-lattice PCF with low Group Velocity Dispersion (GVD) at the anomalous dispersion corresponds to higher dispersion length and higher degree of solitonic interaction. The effective area of square-lattice PCF is always greater than its triangular-lattice counterpart making it better suited for high power applications. Smaller length of symmetric-core PCF for dispersion compensation, while broadband dispersion compensation can be better performed with asymmetric-core PCF. Mid-Infrared SCG can be better performed with asymmetric-core PCF with compressed and high power pulse, while wider range of SCG can be performed with symmetric core PCF. Thus, this study will be extremely useful for realizing fiber towards a custom application around these characteristics.