# Unidirectional Localization of Photons

**Authors:** Hamidreza Ramezani, Pankaj Jha, Yuan Wang, Xiang Zhang

arXiv: 1705.09113 · 2018-02-14

## TL;DR

This paper demonstrates unidirectional photon localization in a spatiotemporally modulated photonic lattice with a defect, breaking reciprocity and enabling directional control of light confinement, with potential applications in non-reciprocal devices.

## Contribution

It introduces a novel method for achieving unidirectional photon localization using a single defect in a modulated lattice that breaks reciprocity.

## Key findings

- Localization occurs only in one direction due to effective magnetic biasing.
- Bandgap shifts depend on the direction of incident light.
- The system provides a pedagogical example of Floquet problems with analytical solutions.

## Abstract

Artificial defects embedded in periodic structures are important foundation for creating localized states with vast range of applications in condensed matter physics, photonics and acoustics. In photonics, localized states are extensively used to confine and manipulate photons. Up to now, all the proposed localized states are reciprocal and restricted by time reversal symmetry. Consequently, localization is bidirectional and photons at the allowed passband in the otherwise forbidden stop band are confined irrespective of the direction of incident beam. In this report, by embedding a single defect in a one-dimensional spatiotemporally modulated photonic lattice, we demonstrate that it is possible to have localization of photon only in one direction. In a spatiotemporally modulated photonics lattice, a time dependent potential generates an effective magnetic biasing, which breaks the reciprocity. Moreover, in such moving lattices the dispersion relation obtains a shift depending on the direction of effective magnetic biasing. A static defect synthesized in a temporally modulated lattice will generate a spatial localization of light in the bandgap. However, due to the shift of the bandgap the localization occurs in different frequencies depending on the direction of incident field. We envisage that this phenomenon might has impact not only in photonics but also other areas of physics and engineering such as condensed matter and acoustics, opens the doors for designing new types of devices such as non-reciprocal traps, sensors, unidirectional tunable filters, and might result in unconventional transports such as unidirectional lasing. Despite its applications, our proposal, namely a defect sate in a driven system, can be considered as a pedagogical example of Floquet problem with analytical solution.

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Source: https://tomesphere.com/paper/1705.09113