Matrix Structure of Metamaterial Absorbers for Multispectral Terahertz Imaging

Kuznetsov, S. А.; Паулиш, А. Г.; Gelfand, Alexander V.; Lazorskiy, Pavel A.; Fedorinin, V. N.

doi:10.2528/pier11101401

Cited by 63 publications

(41 citation statements)

References 25 publications

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“…Since modern practical applications require more sophisticated characteristics, such as larger bandwidths or multiple bands of operation as well as wide-angle and polarization-independent responses, a significant research has been triggered -and yet to be expected -for the improvement of these absorbers' overall behavior [10][11][12][13][14][15][16][17][18][19]. Apparently, this is a critical issue for various electromagnetic interference/electromagnetic compatibility (EMI/EMC) problems, like radar-cross section minimization from airplanes, steamboats and other vehicles, EMI protection owing to mobile phones and local area networks, light-trapping structures for photovoltaic systems or terahertz imaging devices [20][21][22][23][24][25].…”

Section: Introductionmentioning

confidence: 99%

A Family of Ultra-Thin, Polarization-Insensitive, Multi-Band, Highly Absorbing Metamaterial Structures

Kollatou¹,

Dimitriadis²,

Assimonis³

et al. 2013

PIER

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Abstract-The systematic design of size-confined, polarizationindependent metamaterial absorbers that operate in the microwave regime is presented in this paper. The novel unit cell is additionally implemented to create efficient multi-band and broadband structures by exploiting the scalability property of metamaterials. Numerical simulations along with experimental results from fabricated prototypes verify the highly absorptive performance of the devices, so developed. Moreover, a detailed qualitative and quantitative analysis is provided in order to attain a more intuitive and sound physical interpretation of the underlying absorption mechanism. The assets of the proposed concept, applied to the design of different patterns, appear to be potentially instructive for various EMI/EMC configurations.

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Section: Introductionmentioning

confidence: 99%

A Family of Ultra-Thin, Polarization-Insensitive, Multi-Band, Highly Absorbing Metamaterial Structures

Kollatou¹,

Dimitriadis²,

Assimonis³

et al. 2013

PIER

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“…Since numerical and experimental studies of the first splitring-resonator-based MTM structure in the microwave region [1][2][3][4], this kind of structure has been used in many applications such as sensing [1,3,5], absorber [6][7][8], superlensing [9][10][11], and so on. With respect to sensing, MTMs have been proven to be good candidates in the THz regime for highly sensitive chemical or biological detection since the unit cell dimensions are typically sub-wavelength and frequency response can be tuned according to their shape and geometrical dimensions [12][13][14].…”

Section: Introductionmentioning

confidence: 99%

Terahertz Sensing Application by Using Fractal Geometries of Split-Ring Resonators

Ma¹,

Zhang²,

Li³

et al. 2013

PIER

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Abstract-In this study, we report the simulation, fabrication and characterization of a dual-band fractal metamaterial used for terahertz sensing application. By applying the fractal structures of square Sierpinski (SS) curve to the split-ring resonators (SRRs), more compact size and higher sensitivity can be achieved as privileges over conventional SRRs. The influence of different geometrical parameters and the order of the fractal curve on the performances are investigated. Then overlayers are added to the fractal SRRs in order to explore the performance of the entire system in terms of sensing phenomenon. The changes in the transmission resonances are monitored upon variation of the overlayer thickness and permittivity. Measured results show good agreement with simulated data. At the second resonance of the second-order SS-SRRs, maximum frequency shifts of 19.8 GHz, 26.3 GHz and 37.8 GHz were observed for a 2 µm, 4 µm and 10 µm thickness of photoresist. The results show good sensitivity of the sensors suggesting they can be used for a myriad of terahertz sensing applications in biology and chemistry.

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“…Recent years have seen increased interest in the Terahertz (THz) region of the electromagnetic spectrum because of a number of potential applications in industrial quality control, remote sensing, stand-off detection of chemical and biological agents, medical imaging, ultra high speed data communications, all weather visibility systems, astrophysics, and spectroscopy [1][2][3][4]. Although various components have been developed for THz applications [5][6][7][8][9][10][11][12][13][14][15][16][17][18], high power, low cost, and compact THz sources are not readily available [19].…”

Section: Introductionmentioning

confidence: 99%

DESIGN AND 3-D PARTICLE-IN-CELL SIMULATION OF A 140 GHz SPATIAL-HARMONIC MAGNETRON

Esfahani¹,

Tayarani²,

Schunemann³

2013

PIER

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Abstract-This paper discusses design procedure and 3-D numerical simulation of a 140 GHz spatial-harmonic magnetron (SHM). The well known scaling laws and an approximate approach based on single harmonic analysis are used to determine the interaction space dimensions and the optimum geometrical parameters of the side resonators. Numerical simulations of the SHM were performed using CST-Particle Studio. Since the simulations are not based on artificial RF priming or assuming restrictive assumptions on the mode of operation or on the number of harmonics to be considered, electromagnetic oscillations grow naturally from noise. The presented SHM shows stable operation in the π/2 − 1-mode at 140 GHz over a range of DC anode voltages extending from 11.3 kV to 11.5 kV and for an axial magnetic flux density equal to 0.79 T. Output power of the SHM varies from 2 kW to 11 kW over these voltages with a maximum efficiency of about 6.8%.

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Matrix Structure of Metamaterial Absorbers for Multispectral Terahertz Imaging

Cited by 63 publications

References 25 publications

A Family of Ultra-Thin, Polarization-Insensitive, Multi-Band, Highly Absorbing Metamaterial Structures

A Family of Ultra-Thin, Polarization-Insensitive, Multi-Band, Highly Absorbing Metamaterial Structures

Terahertz Sensing Application by Using Fractal Geometries of Split-Ring Resonators

DESIGN AND 3-D PARTICLE-IN-CELL SIMULATION OF A 140 GHz SPATIAL-HARMONIC MAGNETRON

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