Henrik Parsamyan scite author profile

Henrik Parsamyan

4Publications

29Citation Statements Received

85Citation Statements Given

How they've been cited

How they cite others

137

Affiliations

Yerevan State University, Institute of Chemical Physics NAS RA

Publications

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Efficient broadband infrared absorbers based on core-shell nanostructures

2019

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We suggest to exploit dielectric-metal core-shell nanostructures for efficient resonant and yet broadband absorption of infrared radiation with deeply subwavelength configurations. Realizing that nanostructures would efficiently absorb radiation only when their dielectric properties match those of the environment and making use of the effective medium approach, we develop the design strategy using core-shell nanostructures with very thin shells made of poor metals, i.e., metals having real and imaginary parts of their dielectric permittivities of the same order of magnitude. Analyzing in detail spherical and cylindrical core-shell nanostructures, we demonstrate that the resonant infrared absorption can be not only very efficient, i.e., with the absorption cross sections exceeding geometrical ones, but also broadband with the spectral width being of the order of the resonant wavelength. We obtain simple analytical expressions for the absorption resonances in spherical and cylindrical configurations that allow one to quickly identify the configuration parameters ensuring strong infrared absorption in a given spectral range. Relations to effective medium parameters obtained by the internal homogenization are established and discussed. We believe that our results can be used as practical guidelines for realization of efficient broadband infrared absorbers of subwavelength sizes desirable in diverse applications.

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Broadband tunable mid-infrared absorber based on conductive strip-like meta-atom elements

Parsamyan

Haroyan

Nerkararyan

2022

Materials Today Communications

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3D visualization of microwave electric and magnetic fields by using a metasurface-based indicator

Baghdasaryan

Babajanyan

Parsamyan

et al. 2022

Sci Rep

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Visualizations of the microwave electric and magnetic near-field distributions of radio-frequency (RF) filters were performed using the technique of thermoelastic optical indicator microscopy (TEOIM). New optical indicators based on periodic dielectric-metal structures were designed for electric field visualization. Depending on the structure orientation, such metasurface-based indicators allow separately visualization of the Ex and Ey components of the in-plane electric field. Numerical simulations were conducted to examine the working principle of the designed indicator structures, and the results were compared to the experimental, showing good agreement. In addition, the 3D visualization of the microwave near-field distribution was built, to show the field intensity and distribution dependencies on the distance from the RF filter.

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Broadband microwave absorption based on the configuration resonance of wires

2020

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