The finite element method applied to the study of two-dimensional photonic crystals

TL;DR

This paper demonstrates the finite element method's effectiveness in analyzing two-dimensional photonic crystals, including band structures, transmission, and defect modes, offering advantages over traditional methods for complex structures.

Contribution

It introduces FEM as a versatile tool for studying electromagnetic properties of photonic crystals, especially for complex and finite structures, with comparative analysis to existing methods.

Findings

FEM accurately reproduces photonic band structures compared to plane wave methods.

FEM effectively calculates transmission coefficients and quality factors for finite structures.

FEM is robust and suitable for complex, aperiodic photonic crystal analysis.

Abstract

Calculations of the photonic band structure, transmission coefficients, and quality factors of various two-dimensional, periodic and aperiodic, dielectric photonic crystals by using the finite element method (FEM) are reported. The fundamental equations governing the propagation of electromagnetic waves in inhomogeneous media are revisited together with the boundary conditions required for each of the performed calculations. A detailed account of the eigenvalue and harmonic propagation analysis of the electromagnetic problem is reported for several periodic and finite-length structures. It is found that this method reproduces quite well previous results for these lattices obtained with the standard plane wave method with regards to the eigenvalue analysis (photonic band structure calculations). However, in contrast with frequency methods, the finite element method easily allows one to study the time-harmonic propagation of electromagnetic fields and, thus, to calculate the transmission coefficient of finite clusters in a natural way. Moreover, the advantages of using this real space method for structures of arbitrary complexity are also discussed. In addition, point defect cluster quality factor calculations are reported by means of FEM and they are compared to the ones obtained with the FDTD and \texttt{Harminv} methods. As a result, FEM comes out as an effective, stable, robust, and rigorous tool to study light propagation and confinement in both periodic and aperiodic dielectric photonic crystals.