Overview
ABSTRACT
The invention of metamaterials in the 2000s brought a new concept to microwave and optical engineers. There are several types of metamaterials and among them, left-handed materials occupy a special position as they exhibit very different physical effects compared to conventional materials. This article describes firstly the particular physical properties of left-handed metamaterials. The methods of fabrication and characterization of these materials are then presented. Examples of material realizations and applications conclude this article.
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André DE LUSTRAC: Professor Emeritus, Université Paris Nanterre, Centre de nanosciences et de nanotechnologies, Université Paris Saclay
INTRODUCTION
Left-handed materials are known as metamaterials. The term metamaterial dates back to the late 1990s and refers to various classes of artificial materials used in electromagnetics, optics, mechanics, thermics, etc.
In the 1960s, Victor Veselago studied the theoretical properties of an electromagnetic material with simultaneous negative permittivity and permeability. This does not occur in natural materials. V. Veselago showed that electromagnetic waves could propagate in such a material, and that it also had a negative optical index. However, he failed to realize this in practice, and it wasn't until 1999, with two papers by John B. Pendry, that such materials finally became feasible in practice. David R. Smith is then credited with combining the two concepts in a single negative-index material, tested experimentally for the first time in 2000.
This early work in microwaves, and the astonishing properties of the left-hand materials, aroused the interest of researchers all over the world. A flurry of publications followed, in microwaves, terahertz and optics. In the latter field, the technological stakes are high, with predictions of the birth of a new kind of optics, in which the resolution of lenses and optical instruments would no longer be limited by diffraction. This prediction has since been tempered, and its realization remains dependent on advances in nanotechnology.
Examples of metamaterials operating at terahertz, infrared and visible wavelengths were presented. Although there is still room for improvement, they show that in a short space of time, extremely high-performance devices have been produced and tested. This is all the more remarkable given that, in these periodic structures, the elementary cell must have a characteristic size of the order of a tenth of the wavelength. This means that, in the visible range, the cell has a typical size of 50 nm, with details of the order of a few nanometers. We are therefore in the field of nanotechnology, and there are very few laboratories capable of producing this type of structure.
In microwaves, the stakes are different. Applications in telecommunications and electromagnetic compatibility dominate, with different approaches and greater creativity, as technological constraints are less stringent. Studies quickly focused on the development of applications in the field of filters, phase shifters, antennas and materials for electromagnetic compatibility, with systematic comparison to existing technologies and very high performance requirements.
The first part of this article describes the special electromagnetic properties of these left-hand materials (LHMs). In the second part, the methods used to manufacture and characterize these materials...
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KEYWORDS
metamaterials | negative index | evanescent wave | tunnel effect | perfect lensing
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Electromagnetism of materials left hand
Bibliography
Bibliography
Events
JCMM conference: dedicated to microwave materials and characterization https://jcmm2023.sciencesconf.org/
Meta Conference: a conference dedicated to metamaterials http://metaconferences.org/
Metamaterials conference: a conference...
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