Strong spatial dispersion in wire media in the very large wavelength limit

Belov, Pavel A.; Marqués, R.; Maslovski, Stanislav I.; Nefedov, Igor S.; Silveirinha, Mário G.; Simovski, Constantin; Tretyakov, Sergei

doi:10.1103/physrevb.67.113103

Cited by 573 publications

(416 citation statements)

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“…1(a) has been described for an incident electric field parallel to the wires as an artificial dielectric [18][19][20] with an isotropic effective plasma-like relative permittivity ε eff r = 1 − f 2 P /f 2 , where f is the signal frequency, f p is the plasma frequency which depends on the wire diameter and interspacing, see [21][22][23][24] (such medium is assumed to be lossless, which is a reasonable approximation at microwave frequencies). Spatial dispersion should be additionally taken into account when the waves travel at a slant angle to the wire axes [25,26]. For waves propagating normally to the wires, and in the absence of losses, a homogenized wire medium exhibits negative effective permittivity at f < f p (see Fig.…”

Section: Background Electric and Magnetic Resonances In Wire And Srrmentioning

confidence: 99%

Metamaterial made of paired planar conductors: Particle resonances, phenomena and properties

et al. 2009

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The properties and characteristics of a recently proposed anisotropic metamaterial based upon layered arrays of tightly coupled pairs of "dogbone" shaped stripe conductors have been explored in detail. It has been found that a metamaterial composed of such stacked layers exhibits artificial magnetism and may support backward wave propagation. The equivalent network models of the constitutive conductor pairs arranged in the periodic array have been devised and applied to the identification of the specific types of resonances, and to the analysis of their contribution into the effective dielectric and magnetic properties of the artificial medium. The proposed "dogbone" configuration of conductor pairs has the advantage of being entirely realizable and assemblable in planar technology. It also appears more prospective than simple cut-wire or metal-plate pairs because the additional geometrical parameters provide an efficient control of separation between the electric and magnetic resonances that, in turn, makes it possible to obtain a fairly broadband left-handed behaviour of the structure at low frequencies.

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Section: Background Electric and Magnetic Resonances In Wire And Srrmentioning

confidence: 99%

Metamaterial made of paired planar conductors: Particle resonances, phenomena and properties

et al. 2009

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“…An excellent possibility to realize the canalization regime for p-polarization is provided by a wire medium, a material formed by a lattice of parallel conducting wires [30,31,32,33]. This material supports very special type of eigenmodes, so-called transmission line modes [33], which transfer energy strictly along wires with the speed of light and can have arbitrary transverse wave vector components.…”

mentioning

confidence: 99%

“…This material supports very special type of eigenmodes, so-called transmission line modes [33], which transfer energy strictly along wires with the speed of light and can have arbitrary transverse wave vector components. It means that such modes correspond to completely flat isofrequency contour which is the main requirement for implementing the canalization regime.…”

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confidence: 99%

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Subwavelength imaging at optical frequencies using a transmission device formed by a periodic layered metal-dielectric structure operating in the canalization regime

2006

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Imaging with sub-wavelength resolution using a lens formed by periodic metal-dielectric layered structure is demonstrated. The lens operates in canalization regime as a transmission device and it does not involve negative refraction and amplification of evanescent modes. The thickness of the lens have to be an integer number of half-wavelengths and can be made as large as required for ceratin applications, in contrast to the other sub-wavelength lenses formed by metallic slabs which have to be much smaller than the wavelength. Resolution of λ/20 at 600 nm wavelength is confirmed by numerical simulation for a 300 nm thick structure formed by a periodic stack of 10 nm layers of glass with ǫ = 2 and 5 nm layers of metal-dielectric composite with ǫ = −1. Resolution of λ/60 is predicted for a structure with same thickness, period and operating frequency, but formed by 7.76 nm layers of silicon with ε = 15 and 7.24 nm layers of silver with ε = −14.PACS numbers: 78.20. Ci, 42.30.Wb,41.20.Jb The possibility of imaging with sub-wavelength resolution was first reported by Pendry in 2000 [1]. It was shown that the slab of left-handed material [2], a medium with both negative permittivity and permeability, can create images with nearly unlimited resolution. This idea impeached validity of classical restriction on resolution of imaging systems: diffraction limit and became a starting point for creation of new research area of metamaterials [3], artificial media possessing extraordinary electromagnetic properties usually not available in the natural materials. The idea of Pendry's perfect lens is based on such exotic phenomena observable in left-handed media as backward waves, negative refraction and amplification of evanescent waves. The far-field of a source is focused due to effects of backward waves and negative refraction. The near field of the source, which contains sub-wavelength details, is recovered in the image plane because of the amplification of evanescent modes in the slab. Currently, the samples of left-handed materials are created only in microwave region [4]. The creation of lefthanded materials at THz frequencies and in optical range meets with problems related to the difficulty in getting required magnetic properties [5,6] which have to be created artificially. In the absence of magnetic properties the lenses formed by materials with negative permittivity only (for example, silver at optical frequencies) are still capable to create images with sub-wavelength resolution, but the operation is restricted to p-polarization only and the lens has to be thin as compared to the wavelength [1]. This idea was confirmed by recent experimental results [7] which demonstrated the reality of sub-wavelength imaging using silver slabs in optical frequency range. The resolution of such lenses is restricted by losses in the silver, but this problem can be alleviated by cutting the slab into the multiple thin layers [8,9] and introduction of active materials [10]. Unfortunately, at the moment there is no recipe how to incre...

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“…The wire mesh has a period a, and the wires have radius r w . It has been shown that a general wire medium (single, double or triple) suffers from a spatial dispersion [10], [11], nevertheless it can be considered as an isotropic negative permittivity medium near the plasma frequency [12]. A spatial dispersion can be defined as a nonlocal dispersive behavior of the material, i.e., the constitutive permittivity and permeability tensors depend not only on the frequency, but also on the spatial derivatives of the electric and magnetic field vectors or, for plane electromagnetic waves, on the wave-vector components determining the direction of propagation.…”

Section: Introductionmentioning

confidence: 99%