A. Kerkhoff scite author profile

We report the experimental verification of metamaterial cloaking for a 3D object in free space. We apply the plasmonic cloaking technique, based on scattering cancellation, to suppress microwave scattering from a finite-length dielectric cylinder. We verify that scattering suppression is obtained all around the object in the near-and far-field and for different incidence angles, validating our measurements with analytical results and full-wave simulations. Our nearfield and far-field measurements confirm that realistic and robust plasmonic metamaterial cloaks may be realized for elongated 3D objects with moderate transverse cross-section at microwave frequencies.

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Plasmonic cloaking of cylinders: finite length, oblique illumination and cross-polarization coupling

Alù

Rainwater

Kerkhoff

2010

New J. Phys.

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Metamaterial cloaking has been proposed and studied in recent years following several interesting approaches. One of them, the scattering-cancellation technique, or plasmonic cloaking, exploits the plasmonic effects of suitably designed thin homogeneous metamaterial covers to drastically suppress the scattering of moderately sized objects within specific frequency ranges of interest. Besides its inherent simplicity, this technique also holds the promise of isotropic response and weak polarization dependence. Its theory has been applied extensively to symmetrical geometries and canonical 3D shapes, but its application to elongated objects has not been explored with the same level of detail. We derive here closed-form theoretical formulas for infinite cylinders under arbitrary wave incidence, and validate their performance with full-wave numerical simulations, also considering the effects of finite lengths and truncation effects in cylindrical objects. In particular, we find that a single isotropic (idealized) cloaking layer may successfully suppress the dominant scattering coefficients of moderately thin elongated objects, even for finite lengths comparable with the incident wavelength, providing a weak dependence on the incidence angle. These results may pave the way for application of plasmonic cloaking in a variety of practical scenarios of interest.

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Demonstration of an ultralow profile cloak for scattering suppression of a finite-length rod in free space

et al. 2013

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Design of a planar monopole antenna for use with ultra-wideband (UWB) having a band-notched characteristic

Kerkhoff

Líu

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Design and Analysis of Planar Monopole Antennas Using a Genetic Algorithm Approach

Kerkhoff¹,

Rogers²,

Líu

2004

IEEE Trans. Antennas Propagat.

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A. Kerkhoff

Experimental verification of three-dimensional plasmonic cloaking in free-space

Plasmonic cloaking of cylinders: finite length, oblique illumination and cross-polarization coupling

Demonstration of an ultralow profile cloak for scattering suppression of a finite-length rod in free space

Design of a planar monopole antenna for use with ultra-wideband (UWB) having a band-notched characteristic

Design and Analysis of Planar Monopole Antennas Using a Genetic Algorithm Approach

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