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Your search keyword '"Assadillayev, Artyom"' showing total 17 results
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17 results on '"Assadillayev, Artyom"'

1. Nanoscale engineering of optical strong coupling inside metals

Author

Assadillayev, Artyom, Faniayeu, Ihar, Dmitriev, Alexandre, and Raza, Søren

Subjects
Physics - Optics, Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Optical polaritons appear when a material excitation strongly couples to the optical mode. Such strong coupling between molecular transitions and optical cavities results in far-reaching opportunities in modifying fundamental properties of chemical matter. More recently an exciting prospect of cavity-free polaritons has emerged by matter sustaining the optical mode with its geometry. Here we show how strong coupling of the interband transition and surface plasmons can be engineered in nickel at the nanoscale to realize cavity-free optical polaritons inside metals. Using electron energy-loss spectroscopy, we demonstrate that in thin films and nanoantennas the propagation and radiation losses result in a broadening of the plasmon linewidth and a transition from strong to weak coupling. Further, higher-order plasmon resonances couple to the interband transition, and the multipolar coupled states acquire the field profile of the plasmon. Our results provide a fundamental understanding of plasmon-interband coupling in metals and establish the base for the design of unforeseen photocatalytic and magneto-optical nanosystems., Comment: 15 pages, 5 figures

Published
2022

2. Ultraviolet Mie resonances in computationally discovered boron phosphide nanoparticles

Author

Svendsen, Mark Kamper, Sugimoto, Hiroshi, Assadillayev, Artyom, Shima, Daisuke, Fujii, Minoru, Thygesen, Kristian Sommer, and Raza, Søren

Subjects
Physics - Optics, Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Computational Physics
Abstract

Controlling ultraviolet light at the nanoscale using optical Mie resonances holds great promise for a diverse set of applications, such as lithography, sterilization, and biospectroscopy. However, Mie resonances hosted by dielectric nanoantennas are difficult to realize at ultraviolet wavelengths due to the lack of both suitable materials and fabrication methods. Here, we systematically search for improved materials by computing the frequency dependent optical permittivity of 338 binary semiconductors and insulators from first principles, and evaluate their potential performance as high refractive index materials using Mie theory. Our analysis reveals several interesting candidate materials among which boron phosphide (BP) appears particularly promising. We then prepare BP nanoparticles and demonstrate that they support Mie resonances at visible and ultraviolet wavelengths using both far-field optical measurements and near-field electron energy-loss spectroscopy. We also present a laser reshaping method to realize spherical Mie-resonant BP nanoparticles. With a refractive index above 3 and low absorption losses, BP nanostructures advance Mie optics to the ultraviolet.

Published
2021
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3. Disentangling cathodoluminescence spectra in nanophotonics: particle eigenmodes vs transition radiation

Author

Fiedler, Saskia, Stamatopoulou, P. Elli, Assadillayev, Artyom, Wolff, Christian, Sugimoto, Hiroshi, Fujii, Minoru, Mortensen, N. Asger, Raza, Søren, and Tserkezis, Christos

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Optics
Abstract

Cathodoluminescence spectroscopy performed in an electron microscope has proven a versatile tool for analysing the near- and far-field optical response of plasmonic and dielectric nanostructures. Nevertheless, the transition radiation produced by electron impact is often disregarded in the interpretation of the spectra recorded from resonant nanoparticles. Here we show, experimentally and theoretically, that transition radiation can by itself generate distinct resonances which, depending on the time of flight of the electron beam inside the particle, can result from constructive or destructive interference in time. Superimposed on the eigenmodes of the investigated structures, these resonances can distort the recorded spectrum and lead to potentially erroneous assignment of modal characters to the spectral features. We develop an intuitive analogy that helps distinguish between the two contributions. As an example, we focus on the case of silicon nanospheres, and show that our analysis facilitates the unambiguous interpretation of experimental measurements on Mie-resonant nanoparticles.

Published
2021
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4. Thermal near-field tuning of silicon Mie nanoparticles

Author

Assadillayev Artyom, Hinamoto Tatsuki, Fujii Minoru, Sugimoto Hiroshi, and Raza Søren

Subjects
electron energy-loss spectroscopy, high-refractive-index nanostructures, mie resonances, near-field tuning, thermo-optic tuning, Physics, QC1-999
Abstract

Tunable high-refractive-index nanostructures are highly desired for realizing photonic devices with a compact footprint. By harnessing the large thermo-optic effect in silicon, we show reversible and wide thermal tuning of both the far- and near-fields of Mie resonances in isolated silicon nanospheres in the visible range. We perform in situ heating in a transmission electron microscope and electron energy-loss spectroscopy to show that the Mie resonances exhibit large spectral shifts upon heating. We leverage the spectral shifts to demonstrate near-field tuning between different Mie resonances. By combining electron energy-loss spectroscopy with energy-dispersive X-ray analysis, we show a reversible and stable operation of single silicon nanospheres up to a temperature of 1073 K. Our results demonstrate that thermal actuation offers dynamic near-field tuning of Mie resonances, which may open up applications in tunable nonlinear optics, Raman scattering, and light emission.

Published
2021
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5. Nanoscale Engineering of Optical Strong Coupling inside Metals

Author

Assadillayev, Artyom, Faniayeu, Ihar, Dmitriev, Alexandre, Raza, Søren, Assadillayev, Artyom, Faniayeu, Ihar, Dmitriev, Alexandre, and Raza, Søren

Abstract

Optical polaritons appear when a material excitation strongly couples to an optical mode. Such strong coupling between molecular transitions and optical cavities results in far-reaching opportunities in modifying fundamental properties of chemical matter. More recently an exciting prospect of self-coupled polaritons has emerged by matter sustaining the optical mode with its geometry. Here, it is shown how strong coupling of the interband transition and surface plasmons can be engineered in nickel at the nanoscale to realize self-coupled plasmon–interband polaritons inside metals. Using electron energy-loss spectroscopy, it is demonstrated that in nickel thin films and nanoantennas the propagation and radiation losses result in a broadening of the plasmon linewidth and a transition from strong to weak coupling. Further, higher-order plasmon resonances couple to the interband transition, and the multipolar-coupled states acquire the field profile of the plasmon. The results provide a fundamental understanding of plasmon–interband coupling in metals and establish the base for the design of photocatalytic and magneto-optical nanosystems.

Published
2023

10. Mode Hybridization in Silicon Core–Gold Shell Nanosphere

Author

Sugimoto, Hiroshi, Hinamoto, Tatsuki, Kazuoka, Yusuke, Assadillayev, Artyom, Raza, Søren, Fujii, Minoru, Sugimoto, Hiroshi, Hinamoto, Tatsuki, Kazuoka, Yusuke, Assadillayev, Artyom, Raza, Søren, and Fujii, Minoru

Abstract

A dielectric core–metal shell nanosphere has attracted scientific and technological interests due to the unique optical resonances arising from the hybridization of surface plasmon modes and cavity modes. The previous studies focus on a low-index dielectric core without its own optical resonances. Here, optical resonances of a core–shell nanosphere with a high refractive index (n ≈ 4) core with the lowest order Mie resonances in the visible range are investigated theoretically and experimentally. Scattering and absorption spectra of a core–shell nanosphere for different values of the core refractive index are first analyzed, and there is a transition of the hybridization scheme around n ≈ 2. Above the value, a characteristic hybridized mode with strong absorption and weak scattering emerges in the near-infrared range. A core–shell nanosphere composed of a silicon core and a gold shell is prepared, and the resonance modes are studied by single particle scattering spectroscopy and electron energy loss spectroscopy (EELS) in a transmission electron microscope. The core–shell nanospheres exhibit the hybridized modes depending on the core diameter. The hybridized mode as well as the higher order one that is not observable in the scattering spectroscopy is observed in the EELS.

Published
2022

11. Computational Discovery and Experimental Demonstration of Boron Phosphide Ultraviolet Nanoresonators

Author

Svendsen, Mark K., Sugimoto, Hiroshi, Assadillayev, Artyom, Shima, Daisuke, Fujii, Minoru, Thygesen, Kristian S., Raza, Søren, Svendsen, Mark K., Sugimoto, Hiroshi, Assadillayev, Artyom, Shima, Daisuke, Fujii, Minoru, Thygesen, Kristian S., and Raza, Søren

Abstract

Controlling ultraviolet light at the nanoscale using optical Mie resonances holds great promise for a diverse set of applications, such as lithography, sterilization, and biospectroscopy. Access to the ultraviolet requires materials with a high refractive index and wide band gap energy. Here, the authors systematically search for such materials by computing the frequency-dependent optical permittivity of 338 binary semiconductors and insulators from first principles, and evaluate their scattering properties using Mie theory. This analysis reveals several interesting candidate materials among which boron phosphide (BP) appears most promising. Then BP nanoparticles are prepared and it is demonstrated that they support Mie resonances at visible and ultraviolet wavelengths using both far-field optical measurements and near-field electron energy-loss spectroscopy. A laser reshaping method is also presented to realize spherical Mie-resonant BP nanoparticles. With a refractive index over three and low absorption losses in a broad spectral range spanning from the infrared to the near ultraviolet, BP is an appealing material for a broad range of applications in dielectric nanophotonics.

Published
2022

14. Plasmon Launching and Scattering by Silicon Nanoparticles

Author

Assadillayev, Artyom, Hinamoto, Tatsuki, Fujii, Minoru, Sugimoto, Hiroshi, Brongersma, Mark L., Raza, Søren, Assadillayev, Artyom, Hinamoto, Tatsuki, Fujii, Minoru, Sugimoto, Hiroshi, Brongersma, Mark L., and Raza, Søren

Abstract

Resonant optical nanomaterials with a high refractive index, such as silicon, have become key elements for controlling free-space light. Here, we show that silicon nanoparticles can manipulate highly confined guided waves in the form of surface plasmon polaritons (SPPs) on a subwavelength scale. Using electron energy-loss spectroscopy in a transmission electron microscope, we demonstrate that SPPs in ultrathin metal films can be efficiently launched due to the strong coupling between the Mie resonances of the nanoparticle and the SPP modes. We find that the SPP excitation wavelength can be tuned across the entire near-infrared by varying the particle size. For insight into the coupling mechanism, we also measure the electron-beam-induced response of the Mie resonances in isolated silicon nanostructures in a broad size range. Finally, we show that the silicon nanoparticles act as scatterers of the SPPs supported by the film. Our results may pave the way for using high-refractive-index dielectric nanoantennas as compact elements for manipulating highly confined SPPs.

Published
2021

15. Thermal near-field tuning of silicon Mie nanoparticles

Author

Assadillayev, Artyom, Hinamoto, Tatsuki, Fujii, Minoru, Sugimoto, Hiroshi, Raza, Søren, Assadillayev, Artyom, Hinamoto, Tatsuki, Fujii, Minoru, Sugimoto, Hiroshi, and Raza, Søren

Abstract

Tunable high-refractive-index nanostructures are highly desired for realizing photonic devices with a compact footprint. By harnessing the large thermo-optic effect in silicon, we show reversible and wide thermal tuning of both the far-A nd near-fields of Mie resonances in isolated silicon nanospheres in the visible range. We perform in situ heating in a transmission electron microscope and electron energy-loss spectroscopy to show that the Mie resonances exhibit large spectral shifts upon heating. We leverage the spectral shifts to demonstrate near-field tuning between different Mie resonances. By combining electron energy-loss spectroscopy with energy-dispersive X-ray analysis, we show a reversible and stable operation of single silicon nanospheres up to a temperature of 1073 K. Our results demonstrate that thermal actuation offers dynamic near-field tuning of Mie resonances, which may open up applications in tunable nonlinear optics, Raman scattering, and light emission.

Published
2021

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