Terahertz Response of a Microfabricated Rod–Split-Ring-Resonator Electromagnetic Metamaterial

Moser, H. O.; Casse, B. D. F.; Wilhelmi, O.; Saw, B T

doi:10.1103/physrevlett.94.063901

Cited by 229 publications

(111 citation statements)

References 9 publications

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“…[9][10][11][12] These structures usually contain an array of split ring resonators [6,[13][14][15] or dielectric photonic crystals with periodically modulated ε and µ, [2,6,16] which are often complicated to fabricate. To overcome the difficulties, in this paper we predict that negative refraction can take place in a bulk Weyl semimetal (WSM) even without having negative µ and without constructing complicated structure.…”

Section: Introductionmentioning

confidence: 99%

Negative Refraction in Weyl Semimetals

Ukhtary

Nugraha

2017

J. Phys. Soc. Jpn.

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We theoretically propose that Weyl semimetals may exhibit negative refraction at some frequencies close to the plasmon frequency, allowing transverse magnetic (TM) electromagnetic waves with frequencies smaller than the plasmon frequency to propagate in the Weyl semimetals. The idea is justified by the calculation of reflection spectra, in which negative refractive index at such frequencies gives physically correct spectra. In this case, a TM electromagnetic wave incident to the surface of the Weyl semimetal will be bent with a negative angle of refraction. We argue that the negative refractive index at the specified frequencies of the electromagnetic wave is required to conserve the energy of the wave, in which the incident energy should propagate away from the point of incidence.

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Section: Introductionmentioning

confidence: 99%

Negative Refraction in Weyl Semimetals

Ukhtary

Nugraha

2017

J. Phys. Soc. Jpn.

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“…In the last decade, many types of metamaterial structures were suggested such as single split, double split, and electrical split ring resonators operating across various frequency ranges [7][8][9][10][11]. They consist of an array of metallic resonators that interact with electromagnetic waves.…”

Section: Introductionmentioning

confidence: 99%

Effective Sensing Volume of Terahertz Metamaterial with Various Gap Widths

Park

Yoon

Ahn

2016

Journal of the Optical Society of Korea

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We studied experimentally and theoretically the vertical range of the confined electric field in the gap area of metamaterials, which was analyzed for various gap widths using terahertz time-domain spectroscopy. We measured the resonant frequency as a function of the thickness of poly(methyl methacrylate) in the range 0 to 3.2 μm to quantify the effective detection volumes. We found that the effective vertical range of the metamaterial is determined by the size of the gap width. The vertical range was found to decrease as the gap width of the metamaterial decreases, whereas the sensitivity is enhanced as the gap width decreases due to the highly concentrated electric field. Our experimental findings are in good agreement with the finite-difference time-domain simulation results. Finally, a numerical expression was obtained for the vertical range as a function of the gap width. This expression is expected to be very useful for optimizing the sensing efficiency.

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“…Process materials like substrates, resists, and sputter targets should be readily available. State-of-the-art experimental devices were made primarily from -primary pattern generation including direct writing by means of electron, laser, and ion beams [13,41] -UV or X-ray lithography (LIGA) [11,13,15,16,19] -Nanoimprint lithography [50] -Interferometric lithography enhanced by other process steps [14,51] -direct laser writing exploiting two-photon-absorption in resist [44][45][46] -directional evaporation and deposition [47] -electroplating in porous alumina templates [48] -self-rolling of strained layers [52]. Furthermore, Moser et al proposed plastic molding of metamaterials, in particular, of the meta-foil [53].…”

Section: Review Article 221mentioning

confidence: 99%

“…Present day electromagnetic metamaterials in the THz range usually come as composite materials with micro/nanometer range metallic elements, the so-called inclusions, embedded in a plastic matrix or deposited on a dielectric substrate. Figure 1 shows a few selected samples of metamaterials starting with the original GHz rod-splitring materials designed and realized by Pendry et al [8], Smith et al [9,10], and extending to near infrared and optical frequencies [11][12][13][14][15][16][17][18][19][20]. Furthermore, latest developments like the free-standing bi-layer chip [15,16] and, more so, the meta-foil [19] rely on completely self-supported metamaterials that do no longer need matrices or substrates, thus avoiding constraints of their functionality due to dielectric host materials.…”

Section: Introductionmentioning

confidence: 99%

3D THz metamaterials from micro/nanomanufacturing

Moser

Rockstuhl

2011

Laser & Photonics Reviews

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Metamaterials are engineered composite materials offering unprecedented control of wave propagation. Despite their complexity, effective properties can frequently be extracted by conceptualizing them as homogeneous and isotropic media with dispersive electric permittivity and magnetic permeability. For an ideal isotropic medium, strong dispersion in these properties causes wave and field vectors to form a left-handed (E,H,k)-frame involving backward waves, and offering control of quantities like the refractive index which may become negative. Experimental evidence exists from microwaves to the visible. Applications include sub-wavelength-resolution imaging, invisibility cloaking, plasmonics-based lasers, metananocircuits, and omnidirectional absorbers. As the engineered sub-structures must be smaller than their design wavelength, micro/nanomanufacturing is exploited from primary pattern generation over lithography to templating and molecular beam epitaxy. 3D metamaterials have been made by stacking of layers, multilayer structuring, and 3D primary pattern generation. Theory shows that full properties may build up over one or a very few layers.

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Terahertz Response of a Microfabricated Rod–Split-Ring-Resonator Electromagnetic Metamaterial

Cited by 229 publications

References 9 publications

Negative Refraction in Weyl Semimetals

Negative Refraction in Weyl Semimetals

Effective Sensing Volume of Terahertz Metamaterial with Various Gap Widths

3D THz metamaterials from micro/nanomanufacturing

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