Ben Geng Cai scite author profile

Traditionally, a black hole is a region of space with huge gravitational field, which absorbs everything hitting it. In history, the black hole was first discussed by Laplace under the Newton mechanics, whose event horizon radius is the same as the Schwarzschild's solution of the Einstein's vacuum field equations. If all those objects having such an event horizon radius but different gravitational fields are called as black holes, then one can simulate certain properties of the black holes using electromagnetic fields and metamaterials due to the similar propagation behaviours of electromagnetic waves in curved space and in inhomogeneous metamaterials. In a recent theoretical work by Narimanov and Kildishev, an optical black hole has been proposed based on metamaterials, in which the theoretical analysis and numerical simulations showed that all electromagnetic waves hitting it are trapped and absorbed. Here we report the first experimental demonstration of such an electromagnetic black hole in the microwave frequencies. The proposed black hole is composed of non-resonant and resonant metamaterial structures, which can trap and absorb electromagnetic waves coming from all directions spirally inwards without any reflections due to the local control of electromagnetic fields and the event horizon corresponding to the device boundary. It is shown that the absorption rate can reach 99% in the microwave frequencies. We expect that the electromagnetic black hole could be used as the thermal emitting source and to harvest the solar light. * tjcui@seu.edu.cnThe concept of black hole was first introduced by Laplace under the Newton mechanics but has been widely used in the general relativity, in which a Schwarzschild black hole possesses an event horizon radius [1]. Everything hitting it including the light cannot escape from the region because the gravity potential is very powerful, and incident lights which are tangential to this circular horizon from outside would form a circle. Similarly, any object whose possible potential is so powerful that it forms an event horizon could be called as a black hole, just like a recent theoretical work reported in Ref. [3]. Actually, the absorption properties of such a black hole are similar to those of so called black body in thermodynamics [4]. All these black holes have a one-way surface, which absorbs all lights/particles into the horizon surface without any reflections, and hence nothing comes out from the black holes.There are two ways to mimic the phenomena of black holes based on electromagnetic waves and metamaterials [2]. For the black hole in general relativity, the presence of matter-energy densities results in the motion of matter propagating in a curved spacetime [1]. Such a behaviour is very similar to the light or electromagnetic-wave propagation in a curved space or in an inhomogeneous metamaterial. Hence one could use the electromagnetic waves and metamaterials to mimic the celestial mechanics by comparing the refractive index to the metric of gravity [5]. Another w...

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Frequency-Controls of Electromagnetic Multi-Beam Scanning by Metasurfaces

Wan

Cai

et al. 2014

Sci Rep

136

104

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We propose a method to control electromagnetic (EM) radiations by holographic metasurfaces, including to producing multi-beam scanning in one dimension (1D) and two dimensions (2D) with the change of frequency. The metasurfaces are composed of subwavelength metallic patches on grounded dielectric substrate. We present a combined theory of holography and leaky wave to realize the multi-beam radiations by exciting the surface interference patterns, which are generated by interference between the excitation source and required radiation waves. As the frequency changes, we show that the main lobes of EM radiation beams could accomplish 1D or 2D scans regularly by using the proposed holographic metasurfaces shaped with different interference patterns. This is the first time to realize 2D scans of antennas by changing the frequency. Full-wave simulations and experimental results validate the proposed theory and confirm the corresponding physical phenomena.

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Continuous leaky-wave scanning using periodically modulated spoof plasmonic waveguide

Kong

Feng

Cai

et al. 2016

Sci Rep

167

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The plasmonic waveguide made of uniform corrugated metallic strip can support and guide spoof surface plasmon polaritons (SSPPs) with high confinements. Here, we propose periodically-modulated plasmonic waveguide composed of non-uniform corrugated metallic strip to convert SSPPs to radiating waves, in which the main beam of radiations can steer continuously as the frequency changes. To increase the radiation efficiency of the periodically-modulated plasmonic waveguide at the broadside, an asymmetrical plasmonic waveguide is further presented to reduce the reflections and realize continuous leaky-wave scanning. Both numerical simulations and experimental results show that the radiation efficiency can be improved greatly and the main beam of leaky-wave radiations can steer from the backward quadrant to the forward quadrant, passing through the broadside direction, which generally is difficult to be realized by the common leaky-wave antennas.

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Three-Dimensional Gradient-Index Materials and Their Applications in Microwave Lens Antennas

Feng

Cai

Zhang

et al. 2013

IEEE Trans. Antennas Propagat.

129

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Generation of spatial Bessel beams using holographic metasurface

Cai

Jiang

et al. 2015

Opt. Express

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We propose to use backward radiations of leaky waves supported by a holographic metasurface to produce spatial Bessel beams in the microwave frequency regime. The holographic metasurface consists of a grounded dielectric slab and a series of metal patches. By changing the size of metal patches, the surface-impedance distribution of the holographic metasurface can be modulated, and hence the radiation properties of the leaky waves can be designed to realize Bessel beams. Both numerical simulations and experiments verify the features of spatial Bessel beams, which may be useful in imaging applications or wireless power transmissions with the dynamic focal-depth controls.

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Ben Geng Cai

An omnidirectional electromagnetic absorber made of metamaterials

Frequency-Controls of Electromagnetic Multi-Beam Scanning by Metasurfaces

Continuous leaky-wave scanning using periodically modulated spoof plasmonic waveguide

Three-Dimensional Gradient-Index Materials and Their Applications in Microwave Lens Antennas

Generation of spatial Bessel beams using holographic metasurface

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