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Artificial dielectrics

From Wikipedia, the free encyclopedia

Artificial dielectrics are fabricated composite materials, often consisting of arrays of conductive shapes or particles in a nonconductive support matrix, designed to have specific electromagnetic properties similar to dielectrics. As long as the lattice spacing is smaller than a wavelength, these substances can refract and diffract electromagnetic waves, and are used to make lenses, diffraction gratings, mirrors, and polarizers for microwaves. These were first conceptualized, constructed and deployed for interaction in the microwave frequency range in the 1940s and 1950s. The constructed medium, the artificial dielectric, has an effective permittivity and effective permeability, as intended.[1][2]

In addition, some artificial dielectrics may consist of irregular lattices, random mixtures, or a non-uniform concentration of particles.

Artificial dielectrics came into use with the radar microwave technologies developed between the 1940s and 1970s. The term "artificial dielectrics" came into use because these are macroscopic analogues of naturally occurring dielectrics. The difference between the natural and artificial substance is that the atoms or molecules are artificially (human) constructed materials. Artificial dielectrics were proposed because of the need for lightweight structures and components for various microwave delivery devices.[2]

Artificial dielectrics are a direct historical link to metamaterials.

Seminal work

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The term artificial dielectric was originated by Winston E. Kock in 1948 when he was employed by Bell Laboratories. It described materials of practical dimensions that imitated the electromagnetic response of natural dielectric solids. The artificial dielectrics were borne out of a need for lightweight low loss materials for large and otherwise heavy devices.[1][2][3]

Dielectric analog

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A three-dimensional lattice filled with two molecules A and B, here shown as black and white spheres.

Natural dielectrics, or natural materials, are a model for artificial dielectrics. When an electromagnetic field is applied to a natural dielectric, local responses and scattering occur on the atomic or molecular level. The macroscopic response of the material is then described as electric permittivity and magnetic permeability. However, for this macroscopic response to be valid, a type of spatial ordering must be present between the scatterers. In addition, a certain relation to the wavelength is part of its description.[3] A lattice structure, with some degree of spatial ordering is present. Also, the applied field is longer in wavelength than the lattice spacing. This then allows for a macroscopic description expressed as electric permittivity and magnetic permeability.[3]

In order to manufacture an artificial permittivity and permeability there must be a capability to access the atoms themselves. This degree of precision is impractical. However, in the late 1940s - in the domain of long wavelengths such as radio frequencies and microwave - it became possible to manufacture larger scale, and more accessible scatterers that mimic the local response of natural materials - along with a synthesized macroscopic response. In the radio frequency and microwave regions such artificial crystal lattice structures were assembled. The scatterers responded to an electromagnetic field like atoms and molecules in natural materials, and the media behaved much like dielectrics with an effective media response.[3]

The scattering elements are designed to scatter the electromagnetic field in a prescribed manner. The geometric shape of the elements – spheres, disks, conducting strips, etc. – contribute to the design parameters.[3][4]

Rodded medium

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The rodded medium (plasma medium) is also known as the wire mesh, and wire grid. It is a square lattice of thin parallel wires The initial research pertaining to this medium was conducted by J. Brown, K.E. Golden, and W. Rotman.[4][5]

Metamaterials

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Artificial dielectrics are a direct historical link to metamaterials.[2][4]

Further reading

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  • Brown, John, and Willis Jackson. "The properties of artificial dielectrics at centimetre wavelengths." Proceedings of the IEE-Part B: Radio and Electronic Engineering 102.1 (1955): 11-16.
  • Brown, John (October 1953). "Artificial dielectrics having refractive indices less than unity". Proceedings of the IEE - Part IV: Institution Monographs. 100 (5): 51–62. CiteSeerX 10.1.1.192.289. doi:10.1049/pi-4.1953.0009. Date of Current Version: 22 January 2010. See: related articles on IEEE Xplore.
  • Golden, Kurt E. A study of artificial dielectrics. No. TDR-269 (4280-10)-4. Aerospace Corp.(1964) El Segundo, Ca.
  • Lalanne, Philippe, and Mike Hutley. "The optical properties of artificial media structured at a subwavelength scale." Encyclopedia of Optical Engineering (2003): 62-71.(Free PDF download)
  • Rotman, Walter. "Plasma simulation by artificial dielectrics and parallel-plate media." Antennas and Propagation, IRE Transactions on 10.1 (1962): 82-95.
  • Silin, R. A. (1972). "Optical properties of artificial dielectrics (review)". Radiophysics and Quantum Electronics. 15 (6): 615–624. Bibcode:1972R&QE...15..615S. doi:10.1007/BF01039343. S2CID 120809150.
  • A Luneburg Lens for the SKA Summary of the MNRF research project into the manufacture of a low-cost microwave refracting spherical lens for radioastronomy, proposes the use of artificial dielectrics.
  • A lens constructed of uniform spherical shells seems feasible.
  • Collin, R. E., Field Theory of Guided Waves, 2nd ed., Wiley-IEEE, 1991 (Chapter 12).

References

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  1. ^ a b Milonni, Peter W.; Institute of Physics (November 30, 2004). Fast light, slow light and left-handed light. CRC Press. pp. 221, 222. ISBN 978-0-7503-0926-4. First published in 2004 according to the CRC Press web page Archived September 28, 2011, at the Wayback Machine for this book. According to the copyright page of this book, accessible via Google Books, it had gone into its tenth printing by sometime in 2005.
  2. ^ a b c d Wenshan, Cai; Shalaev, Vladimir (November 2009). Optical Metamaterials: Fundamentals and Applications. Springer. pp. xi, 3, 8, 9, 59, 74. ISBN 978-1-4419-1150-6.
  3. ^ a b c d e Eleftheriades, George V.; Balmain, Keith (July 2005). Negative-refraction metamaterials: fundamental principles and applications. John Wiley & Sons, Inc. pp. v, xiii, xiv, 4–7, 46, 47, 53. ISBN 978-0-471-60146-3. Copyright held by the Institute of Electrical Engineers.
  4. ^ a b c Capolino, Filippo (October 5, 2009). Theory and Phenomena of Metamaterials. CRC Press. pp. 1–1 to 1–8. ISBN 978-1-4200-5425-5.
  5. ^ Initial research on rodded medium.
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