# Active beam steering and afocal zooming by nematic liquid crystal   infiltrated graded index photonic structures

**Authors:** Ceren Babayigit, Hamza Kurt, Mirbek Turduev

arXiv: 1902.07534 · 2019-09-04

## TL;DR

This paper introduces a novel active beam steering and zooming device using nematic liquid crystals infiltrated in graded index photonic structures, enabling voltage-controlled light manipulation without mechanical parts.

## Contribution

It presents a new design of GRIN photonic crystal structures infiltrated with liquid crystals for electrically tunable beam steering and zooming applications.

## Key findings

- Achieved beam deflection of 44 degrees.
- Demonstrated light magnification up to 2.15 times.
- Device operates under low voltage and power conditions.

## Abstract

This study presents active beam steering and afocal zooming of light by incorporating liquid crystals (LCs) with graded index photonic crystal (GRIN PC). The GRIN PC structures are composed of low refractive index polymer annular rods having gradually varied radii of holes. To actively manipulate incident light, the annular rods are infiltrated with nematic LCs. By applying an external voltage to the infiltrated LCs, the effective index profile of the low-index GRIN PC structure is modulated without introducing any mechanical movement. The incident beam deflection and corresponding focal distance modulation are tuned only by controlling the applied bias voltage. In the present work, hyperbolic secant refractive index profile is chosen to design GRIN PC structures. To design GRIN PC structure with annular PCs, Maxwell-Garnett effective medium approximation is employed. Moreover, we analytically express the relation between infiltrated LCs and gradient parameter to show the physical background of the tuning ability of the proposed devices. Also, beam steering and afocal zooming devices are analytically investigated via geometrical optics and numerically realized with the help of the finite-difference time-domain method. A beam deflection with an angle change of {\Delta}{\theta}out= 44{\deg} and a light magnification with maximum x2.15 are obtained. LCs are inexpensive materials and work under low voltage/power condition. This feature can be used for designing an electro-optic GRIN PC device that can be useful in various optical applications.

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Source: https://tomesphere.com/paper/1902.07534