Metamaterial

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A metamaterial (or meta material) is a material which gains its properties from its structure rather than directly from its composition. To distinguish metamaterials from other composite materials, the metamaterial label is usually used for a material which has unusual properties. The term was coined in 1999 by Rodger M. Walser of the University of Texas at Austin. He defined metamaterials as:^[1]

Macroscopic composites having a manmade, three-dimensional, periodic cellular architecture designed to produce an optimized combination, not available in nature, of two or more responses to specific excitation.

Among electromagnetics researchers, the term is often used, quite narrowly, for materials which exhibit negative refraction.

The first metamaterials were developed by W.E. Kock in the late 1940s with metal-lens antennas^[2] and metallic delay lenses^[3].

Contents 1 Electromagnetic metamaterials 2 Negative refractive index 3 Development and applications 4 Theoretical models 5 See also 6 References 7 External links 7.1 Research groups (in alphabetical order) 7.2 Internet portals 7.3 More articles and presentations (newest is first)

[edit] Electromagnetic metamaterials

Metamaterials are of particular importance in electromagnetism (especially optics and photonics). They show promise for a variety of optical and microwave applications such as new types of beam steerers, modulators, band-pass filters, lenses, microwave couplers, and antenna radomes.

In order for its structure to affect electromagnetic waves, a metamaterial must have structural features smaller than the wavelength of the electromagnetic radiation it interacts with. For instance, if a metamaterial is to behave as a homogeneous material accurately described by an effective refractive index, the feature sizes must be much smaller than the wavelength. For visible light, which has wavelengths of less than one micrometre typically (560 nanometers for sunlight), the structures are generally half or less than half this size; i.e., less than 280 nanometres. For microwave radiation, the structures need only be on the order of one decimetre. Microwave frequency metamaterials are almost always artificial, constructed as arrays of current-conducting elements (such as loops of wire) which have suitable inductive and capacitive characteristics.

Metamaterials usually consist of periodic structures, and thus have many similarities with photonic crystals and frequency selective surfaces. However, these are usually considered to be distinct from metamaterials, as their features are of similar size to the wavelength at which they function, and thus cannot be approximated as a homogeneous material.

[edit] Negative refractive index

The main reason researchers have investigated metamaterials is the possibility to create a structure with a negative refractive index, since this property is not found in any naturally occurring material. Almost all materials encountered in optics, such as glass or water, have positive values for both permittivity ε and permeability μ. However, many metals (such as silver and gold) have negative ε at visible wavelengths. A material having either (but not both) ε or μ negative is opaque to electromagnetic radiation (see surface plasmon for more details).

Although the optical properties of a transparent material are fully specified by the parameters ε and μ, in practice the refractive index N is often used. N may be determined from. All known transparent materials possess positive values for ε and μ. By convention the positive square root is used for N.

However, some engineered metamaterials have ε < 0 and μ < 0; because the product εμ is positive, N is real. Under such circumstances, it is necessary to take the negative square root for N. Physicist Victor Veselago proved that such substances can transmit light.

The foregoing considerations are simplistic for actual materials, which must have complex-valued ε and μ. The real parts of both ε and μ do not have to be negative for a passive material to display negative refraction.^[4]

Metamaterials with negative N have numerous startling properties:

• Snell's law (N₁sinθ₁ = N₂sinθ₂) still applies, but as N₂ is negative, the rays will be refracted on the same side of the normal on entering the material.
• The Doppler shift is reversed: that is, a light source moving toward an observer appears to reduce its frequency.
• Cherenkov radiation points the other way.
• The time-averaged Poynting vector is antiparallel to phase velocity. This means that unlike a normal right-handed material, the wave fronts are moving in the opposite direction to the flow of energy.

For plane waves propagating in such metamaterials, the electric field, magnetic field and wave vector follow a left-hand rule, thus giving rise to the name left-handed (meta)materials. It should be noted that the terms left-handed and right-handed can also arise in the study of chiral media, but their use in that context is unrelated to this effect. Some researchers consider the qualifier left-handed for achiral materials as particularly infelicitous.

The effect of negative refraction is analogous to wave propagation in a left-handed transmission line, and such structures have been used to verify some of the effects described here.

[edit] Development and applications

The first metamaterials were developed by W.E. Kock in the late 1940's Metal-lens antennas, IRE Proc., 34 November 1946, pp. 828-836 and Metallic delay lenses, Bell. Sys. Tech. Jour.,27, January 1948, pp. 58-82.

The unique properties of metamaterials were verified by full-wave analysis in Caloz et al. (2001).^[5] However, the LH structures devised up to 2002 were impractical for microwave applications, because they had a too narrow bandwidth and were quite lossy. Eleftheriades et al. (2002), and Caloz et al. (2002) provided a method to realize left-handed metamaterials using artificial lumped-element loaded transmission lines in microstrip technology.^[6][7]

The first superlens with a negative refractive index provided resolution three times better than the diffraction limit and was demonstrated at microwave frequencies at the University of Toronto by A. Grbic and G.V. Eleftheriades^[8]. Subsequently, the first optical superlens (an optical lens which exceeds the diffraction limit) was created and demonstrated in 2005 by Xiang Zhang et al. of UC Berkeley, as reported that year in the April 22 issue of the journal Science.^[9] But their lens didn't rely on negative refraction. Instead, they used a thin silver film to enhance the evanescent modes through surface plasmon coupling. This idea was first suggested by John Pendry in Physical Review Letters.

Metamaterials have been proposed as a mechanism for building a cloaking device. These mechanisms typically involve surrounding the object to be cloaked with a shell which affects the passage of light near it.^[10] Duke University and Imperial College London are currently researching this use of metamaterials and have managed to use metamaterials to cloak an object (in the microwave spectrum) using special concentric rings; the microwaves were barely affected by the presence of the cloaked object.^[11] In early 2007, a metamaterial with a negative index of refraction for visible light wavelengths was announced by a joint team of researchers at the Ames Laboratory of the United States Department of Energy and at Karlsruhe University in Germany. The material had an index of -0.6 at 780 nanometers.^[12]

Metamaterials have been also proposed for designing agile antennas.^[13]

[edit] Theoretical models

Left-handed (LH) materials were first introduced theoretically by Victor Veselago in 1967^[14][15].

J. B. Pendry was the first to theorize a practical way to make a left-handed metamaterial (LHM). 'Left-handed' in this context means a material in which the 'right-hand rule' is not obeyed, allowing an electromagnetic wave to convey energy (have a group velocity) in the opposite direction to its phase velocity. Pendry's initial idea was that metallic wires aligned along propagation direction could provide a metamaterial with negative permittivity (ε<0). Note however that natural materials (such as ferroelectrics) were already known to exist with negative permittivity: the challenge was to construct a material which also showed negative permeability (µ<0). In 1999, Pendry demonstrated that an open ring ('C' shape) with axis along the propagation direction could provide a negative permeability. In the same paper, he showed that a periodic array of wires and ring could give rise to a negative refractive index. A related negative permeability particle which was also proposed by Professor Pendry is the Swiss roll.

The analogy is as follows: Natural materials are made of atoms, which are dipoles. These dipoles modify the light velocity by a factor n (the refractive index). The ring and wire units play the role of atomic dipoles: the wire acts as a ferroelectric atom, while the ring acts as an inductor L and the open section as a capacitor C. The ring as a whole therefore acts as a LC circuit. When the electromagnetic field passes through the ring, an induced current is created and the generated field is perpendicular to the magnetic field of the light. The magnetic resonance results in a negative permeability; the index is negative as well. (The lens is not truly flat as the C and its nearby Cs imposes a slope for the electric induction.)

[edit] See also

• List of emerging technologies
• Transformation optics

[edit] References

1. ^ R.M. Walser, in: W.S. Weiglhofer and A. Lakhtakia (Eds.), [http://spie.org/x648.xml?product_id=504610 Introduction to Complex Mediums for Electromagnetics and Optics], SPIE Press, Bellingham, WA, USA, 2003
2. ^ IRE Proc., 34 November 1946, pp. 828-836
3. ^ Bell. Sys. Tech. Jour., 27, January 1948, pp. 58-82
4. ^ R.A. Depine and A. Lakhtakia, A new condition to identify isotropic dielectric-magnetic materials displaying negative phase velocity, Microwave and Optical Technology Letters, Vol. 41, pp. 315-316, 2004
5. ^ C. Caloz, C.-C. Chang, and T. Itoh, "Full-wave verification of the fundamental properties of left-handed materials in waveguide configurations," J. Appl. Phys. 2001, 90(11).
6. ^ G.V. Eleftheriades, A.K. Iyer and P.C. Kremer, "Planar negative refractive index media using periodically L-C loaded transmission lines," IEEE Trans. on Microwave Theory and Techniques, vol. 50, no. 12, pp. 2702-2712, 2002
7. ^ C. Caloz and T. Itoh, "Application of the transmission line theory of left-handed (LH) materials to the realization of a microstrip 'LH line'," IEEE Antennas and Propagation Society International Symposium, 2002, 2, 412-415 (doi 10.1109/APS.2002.1016111).
8. ^ A. Grbic and G.V. Eleftheriades, "Overcoming the diffraction limit with a planar left-handed transmission-line lens," Physical Review Letters, vol. 92, no. 11, pp. 117403 , March 19, 2004
9. ^ New superlens opens door to nanoscale optical imaging, high-density optoelectronics
10. ^ http://cnn.com/2006/TECH/05/25/invisibility.cloak.ap/index.html
11. ^ News Releases, Feature Stories and Profiles about Duke University's Pratt School of Engineering
12. ^ Metamaterials found to work for visible light
13. ^ http://membres.lycos.fr/hocine/TAPCEBG.pdf
14. ^ Veselago VG (1968). "The electrodynamics of substances with simultaneously negative values of ε and μ". Sov. Phys. Usp. 10 (4): 509-14. doi:10.1070/PU1968v010n04ABEH003699. 
15. ^ Veselago VG (1967). "The electrodynamics of substances with simultaneously negative values of ε and μ" (in Russian). Usp. Fiz. Nauk 92: 517-526. 

[edit] External links

[edit] Research groups (in alphabetical order)

1. Allan Boardman's Group - UK
2. Christophe Caloz' research group — Canada
3. George Eleftheriades's research group — Canada
4. Nader Engheta - US
5. FGAN-FHR — Germany
6. M. Saif Islam's Research Group, University of California at Davis - USA
7. Tatsuo Itoh`s group — USA
8. Akhlesh Lakhtakia - USA
9. Antennas & Electromagnetics Group, Queen Mary, University of London - UK
10. Herbert Moser's Group, Singapore Synchrotron Light Source — Singapore
11. Ekmel Özbay`s Research group, Bilkent University - Turkey
12. Sir John Pendry's group — References — Imperial College — UK
13. Willie Padilla's research group — Boston College — USA
14. Viktor Podolskiy's group — Oregon State University — USA
15. Vladimir Shalaev's Research Group, Purdue University, USA
16. Shvets Research Group, University of Texas at Austin - USA
17. David Smith's research group — Duke University — USA
18. Costas Soukoulis at IESL, Greece — Photonic, Phononic & MetaMaterials Group
19. Srinivas Sridhar's Group, Northeastern University — USA
20. Virtual Institute for Artificial Electromagnetic Materials and Metamaterials ("METAMORPHOSE VI AISBL")
21. "Metamorphose" EU Network of Excellence on Metamaterials. Coordinator: Sergei Tretyakov
22. Irina Veretennicoff's research group, Vrije Universiteit Brussel — Belgium
23. Martin Wegener's Metamaterials group, Universität Karlsruhe (TH) — Germany
24. Georgios Zouganelis's Metamaterials Group, NIT — Japan
25. Xiang Zhang's group, Berkeley USA
26. Applied Electromagnetics Laboratory, Lucio Vegni's group, Università "Roma Tre", Rome
27. Takuo Tanaka and Satoshi Kawata, Nanophotonics Lab., RIKEN (The Institute of Physical and Chemical Research), Japan
28. Said Zouhdi's group, LGEP at SUPELEC, France
29. Sergei Tretyakov's group, Helsinki University of Technology, Finland
30. CIMITEC, Universitat Autònoma de Barcelona, Spain
31. Sambles and Barnes Research Group, University of Exeter - UK

[edit] Internet portals

1. Journal "Metamaterials" published by Elsevier (homepage)
2. Online articles: "Metamaterials" in ScienceDirect
3. RSS feed for Metamaterials articles published in Physical Review Journals
4. MetaMaterials.net Web Group
5. Virtual Institute for Artificial Electromagnetic Materials and Metamaterials ("METAMORPHOSE VI AISBL")
6. European Network of Excellence "METAMORPHOSE" on Metamaterials

[edit] More articles and presentations (newest is first)

1. UWB Tunable Delay System, Prof Christophe Caloz, Ecole Polytechnique de Montreal)
2. Metaphotonics.de - Information about Photonic Metamaterials in Karlsruhe (HHNG Dr. Stefan Linden and Prof. Dr. Martin Wegener)
3. Realistic raytraced images, videos and interactive web-based demonstrations of materials with negative index of refraction.
4. Cloaking devices, nihility bandgap, LF magnetic enhancement, perfect radome NIT Japan
5. Left-Handed Flat Lens HFSS Tutorial EM Talk Tutorial
6. Journal of Optics A, February 2005 Special issue on Metamaterials
7. Experimental Verification of a Negative Index of Refraction
8. How To Make an Object Invisible
9. Metamaterials hold key to cloak of invisibility