Multi-directional cloak design by all dielectric unit-cell optimized structure

TL;DR

This paper presents a novel multi-directional optical cloaking design using all dielectric unit-cells optimized through genetic algorithms, experimentally validated at microwave scale, with potential applications in nanoscales and acoustics.

Contribution

It introduces an optimized dielectric structure for multi-directional cloaking, combining numerical design with experimental microwave validation, advancing cloaking technology.

Findings

Successful microwave-scale cloaking demonstration

Good agreement between simulations and experiments

Potential for application in optical and acoustic cloaking

Abstract

In this manuscript, we demonstrate the design and experimental proof of an optical cloaking structure which multi-directionally conceals a perfectly electric conductor (PEC) object from an incident plane wave. The dielectric modulation around the highly reflective scattering PEC object is determined by an optimization process for multi-directional cloaking purposes. And to obtain the multi-directional effect of the cloaking structure, an optimized slice is mirror symmetrized through a radial perimeter. Three-dimensional (3D) finite-difference time-domain method is integrated with genetic optimization to achieve cloaking design. In order to overcome the technological problems of the corresponding devices in the optical range and to experimentally demonstrate the proposed concept, our experiments were carried out on a scale model in the microwave range. The scaled proof-of-concept of proposed structure is fabricated by 3D printing of polylactide material, and the brass metallic alloy is used as a perfect electrical conductor for microwave experiments. A good agreement between numerical and experimental results is achieved. The proposed design approach is not restricted only to multi-directional optical cloaking but can also be applied for different cloaking scenarios dealing with electromagnetic waves in nanoscales as well as other types of such as acoustic waves. Using nanotechnology, our scale proof-of-concept research will take the next step towards the creation of "optical cloaking" devices.