The role of symmetrical inhomogeneity in problems of electromagnetic wave propagation

TL;DR

This paper explores how symmetrical inhomogeneity in media, such as gradient index materials and photonic crystals, affects electromagnetic wave propagation, with a focus on Maxwell Fish eye profiles and their optical effects.

Contribution

It provides a detailed analysis of electromagnetic wave behavior in symmetric inhomogeneous media, including Maxwell Fish eye profiles and periodic structures, highlighting their unique optical effects.

Findings

Maxwell Fish eye profile causes unique focusing effects.

Symmetric inhomogeneity influences wave propagation and device design.

Periodic inhomogeneity in photonic crystals affects bandgap properties.

Abstract

Media with symmetric inhomogeneity have been of great interest due to numerous effects which occur when electromagnetic waves propagate through such media. In general, the inhomogeneity of a certain medium means that the refraction index of the medium is not constant and has some sort of spatial dependency. These types of media are called gradient index (GRIN) media. Different optical effects related to GRIN media are described by GRIN optics. GRIN optics examines different phenomena related to the gradient of the refractive index of the medium and/or the material. Electromagnetic waves propagating in such materials result in many effects that are being exploited to produce lenses, optical fibers, and other devices. By symmetric inhomogeneity, we refer to the case when the inhomogeneity of the medium or material is not an arbitrary function of position but has some sort of symmetry. In this dissertation, our primary focus is on two types of inhomogeneous media. Firstly, we examine photonic crystals which are optical structures where the refractive index changes periodically. The other type of inhomogeneity, that is examined, is the case when the refractive index of a medium is a continuous function of position. Moreover, the central focus is given to profiles possessing different symmetries. Specifically, we investigate the effects occurring in Maxwell Fish eye profile which has spherical symmetry as well as an extended symmetry which will be thoroughly studied in Chapters 3 and 4.