3-D Metamaterials: Trends on Applied Designs, Computational Methods and Fabrication Techniques

TL;DR

This paper reviews the evolution and future prospects of 3-D metamaterials, emphasizing advances in computational design, innovative structures, and fabrication methods to unlock their full potential for advanced wave manipulation.

Contribution

It provides a comprehensive overview of recent trends in 3-D metamaterials, highlighting new computational approaches, design innovations, and manufacturing techniques.

Findings

Enhanced wave control capabilities in 3-D configurations

Development of efficient computational methods for design

Innovative fabrication techniques enabling complex 3-D structures

Abstract

Metamaterials are artificially engineered devices that go beyond the properties of conventional materials in nature. Metamaterials allow the creation of negative refractive indexes, light trapping with epsilon-near-zero compounds, bandgap selection, superconductivity phenomena, non-Hermitian responses and, more generally, to manipulate the propagation of electromagnetic and acoustic waves. In the past, low computational resources and the lack of proper manufacturing techniques have limited the attention to 1-D and 2-D metamaterials. However, the true potential of metamaterials will be ultimately reached in 3-D configurations, when the degrees of freedom associated to the propagating direction are finally exploited in design. This is expected to lead to a new era in metamaterial field, from which future high-speed and low-latency communication networks can benefit. Here, a comprehensive overview of the past, present and future trends related to 3-D metamaterial devices is presented, focusing on efficient computational methods, innovative designs and functional manufacturing techniques.