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101 results on '"Sibilia Concita"'

1. Active infrared tuning of metal–insulator-metal resonances by VO2 thin film.

Author

Petronijevic, Emilija, Larciprete, Maria Cristina, Centini, Marco, Pronti, Lucilla, Aglieri, Vincenzo, Razzari, Luca, Toma, Andrea, Macaluso, Roberto, Voti, Roberto Li, and Sibilia, Concita

Abstract

VO2 is a promising phase change material offering a large contrast of electric, thermal, and optical properties when transitioning from semiconductor to metallic phase. Here we show that a hybrid metamaterial obtained by proper combination of a VO2 layer and a nanodisk gold array provides a tunable plasmonic gap resonance in the infrared range. Specifically, we have designed and fabricated a metal–insulator-metal gap resonance by inserting sub-wavelength VO2 film between a flat gold layer and a gold nanodisk resonator array. The resonance of the hybrid metamaterial is centered in the useful 3–5 μm range when VO2 is in its semiconductor state. The experimental study highlights a monotonical spectral tuning of the resonance when increasing temperature up to 50 °C above the room temperature, providing a continuous resonance shift of almost 1 μm in the mid-infrared range. Wavelength range and intensity tunability can be further optimized by modifying the thicknesses of the layers and metamaterial parameters. [ABSTRACT FROM AUTHOR]

Published
2024
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3. Photo-acoustic technique with widely tuneable laser: Metasurface circular dichroism response.

Author

Skubisz, Claudia, Petronijevic, Emilija, Leahu, Grigore, Cesca, Tiziana, Scian, Carlo, Mattei, Giovanni, Sibilia, Concita, and Belardini, Alessandro

Subjects
MIRROR symmetry, MOLECULAR interactions, LASERS, CHIRALITY, HEAT transfer, ACOUSTIC imaging, CIRCULAR dichroism, PERIODONTAL probe
Abstract

Chirality, an intrinsic property of certain entities in the universe, is characterized by the absence of mirror symmetry. Understanding chirality is crucial as it influences molecular interactions and properties. Circular dichroism (CD), measured using circularly polarized light, is a standard technique for probing chirality, but its sensitivity is often limited. Here, we explore extrinsic chirality (i.e. a property arising from asymmetric achiral materials when observed from out of normal incidence directions), using photo-acoustic spectroscopy (PAS). PAS allows direct measurement of local absorption, by monitoring the heat produced and transferred to the surrounding air, regardless the transmitted, reflected, and scattered light that flows away from the sample. In conventional techniques, the CD is usually measured by taking into account only the extinction as transmitted (or reflected) light. In this study, we introduce a new PAS setup that employs an oblique-incidence laser to study extrinsic chirality in silver-coated self-assembled metasurfaces. Our experimental results reveal intriguing CD trends dependent on the angle of incidence and wavelength, indicative of extrinsic chirality. This study expands the application of PAS, enabling simultaneous analysis of multiple wavelengths and providing valuable insights into chiral metasurfaces. [ABSTRACT FROM AUTHOR]

Published
2024
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4. Tailoring second harmonic emission by ZnO nanostructures: Enhancement of directionality.

Author

Petronijevic, Emilija and Sibilia, Concita

Subjects
ZINC oxide, OPTICAL communications, SEMICONDUCTOR design, OPTICAL properties, NANOPHOTONICS, NANOSTRUCTURES
Abstract

Tailoring nonlinear optical properties at the nanoscale is a hot topic in nowadays nanophotonics, promising for applications spanning from sensing to ultrafast optical communications. Here we present a numerical approach of designing a simple semiconductor nanostructure able to tailor second harmonic emission in the near- and far-field. We start from linear simulations of ZnO nanospheres, which reveal multipolar nature of the scattering. Next, we show how the same nanospheres, with radii in 30–130 nm range, excited at 800 nm, manipulate the directivity of the emitted second harmonic. We observe that the nanospheres which exhibit Kerker condition at 400 nm, emit the second harmonic field in the forward direction. We further investigate how the asymmetry (ellipsoid geometry) tailors the second harmonic directivity. We finally introduce geometry with low chiro-optical response, and observe that the second harmonic far-field depends on the handedness of the light exciting the nanostructure at 800 nm. [ABSTRACT FROM AUTHOR]

Published
2024
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5. Active Modulation of Er3+ Emission Lifetime by VO2 Phase‐Change Thin Films.

Author

Kalinic, Boris, Cesca, Tiziana, Lovo, Alessandro, Scian, Carlo, Macaluso, Roberto, Bovino, Fabio, Li Voti, Roberto, Sibilia, Concita, and Mattei, Giovanni

Subjects
THIN films, OPACITY (Optics), OPTICAL diffraction, LIGHT sources, OPTICAL modulation
Abstract

The active modulation of optical response of quantum emitters at the nanoscale is of paramount importance to realize tunable light sources for nanophotonic devices. Herein, a thin film of phase‐change material (VO2) is coupled to a 20 nm‐thick silica layer embedding Er3+ ions, and it is demonstrated how the active tuning of the local density of optical states near the erbium emitters provided by the thermally induced semiconductor‐to‐metal transition of VO2 can be used to dynamically control the Er3+ emission lifetime at telecom wavelength (1.54 μm). A decay rate contrast of a factor 2 is obtained between high temperature (90 °C), when VO2 is metallic, and room temperature, when VO2 is semiconductor, in agreement with calculations performed with the classical dipole oscillator analytical model. A hysteretic behavior is observed by measuring the Er3+ lifetime as a function of the temperature, whose parameters are consistent with those of grazing incidence X‐ray diffraction and optical transmittance measurements. The fractions of Er3+ ions that couple with VO2 in each phase at the different temperatures are determined by the analysis of the temporal decays. The results make the investigated system an optimal candidate for the development of tunable photon sources at telecom wavelength. [ABSTRACT FROM AUTHOR]

Published
2024
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6. Tunable IR perfect absorbers enabled by tungsten doped VO2 thin films.

Author

Larciprete, Maria Cristina, Ceneda, Daniele, Scirè, Daniele, Mosca, Mauro, Persano Adorno, Dominique, Dereshgi, Sina Abedini, Macaluso, Roberto, Li Voti, Roberto, Sibilia, Concita, Cesca, Tiziana, Mattei, Giovanni, Aydin, Koray, and Centini, Marco

Subjects
PHASE transitions, THIN films, TRANSITION temperature, CRITICAL temperature, TUNGSTEN, THERMOCHROMISM, SUPERCONDUCTING transition temperature
Abstract

The temperature tunability of complex dielectric constants of vanadium dioxide (VO2) makes it a promising phase-change material for use in active, dynamic, tunable photonics applications. Specifically, the semiconductor-to-metal phase transition in VO2 enables reversible, broadband, and large complex refractive index variation and paves the way for a plethora of applications. Although the critical temperature for phase-transition is 68 °C for VO2 films, its transition temperature can be reduced to room temperature by tungsten-doping of vanadium dioxide. Such a degree of freedom in controlling the critical temperature through tungsten doping provides further tunability of the thermochromic behavior. In this work, we investigate a variety of W-doped VO2 thin films deposited by laser ablation of targets with increasing W doping content and report detailed infrared characterization together with numerical simulations. Our experimental results indicate that the perfect absorption can be achieved at different temperatures, within the VO2 insulator-to-metal phase transition process, as a function of W doping content. Tunable subwavelength layers allow perfect absorption under different temperature conditions around λ = 12 µm. We show that a high dynamic range of reflectivity can be achieved when the temperature is increased above the phase transition temperature. Furthermore, we observe perfect absorption at 11.8 µm at room temperature for a W content of 0.75%. We believe that W-doped VO2 thin films with tunable and controllable perfect absorption will open the way for a class of promising thermo-optical devices including thermos-photovoltaics, infrared filters, radiative cooling devices, and thermal emitters. [ABSTRACT FROM AUTHOR]

Published
2023
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8. Broadband, angle-dependent optical characterization of asymmetric self-assembled nanohole arrays in silver.

Author

El-Ansary, Zakaria., Ram Kumar, Hari Prasath., Brioual, Bilal., Petronijevic, Emilija., Cesca, Tiziana., Scian, Carlo., Mattei, Giovanni., El Hasnaoui, Mohamed., Sibilia, Concita., and Belardini, Alessandro.

Subjects
NANOSTRUCTURED materials, LINEAR polarization, CIRCULAR polarization, PLASMONICS, COMPUTER simulation, INFRARED lasers
Abstract

Plasmonic nanostructured materials made of nanohole arrays in metal are significant plasmonic devices exhibiting resonances and strong electromagnetic confinement in the visible and near-infrared range. As such, they have been proposed for use in many applications such as biosensing and communications. In this work, we introduce the asymmetry in nanoholes, and investigate its influence on the electromagnetic response by means of broadband experimental characterization and numerical simulations. As a low-cost fabrication process, we use nanosphere lithography, combined with tilted silver evaporation, to obtain a 2D hexagonal array of asymmetric nanoholes in Ag. Our experimental set-up is based on a laser, widely tunable in the near-infrared range, with precise polarization control in the input and in the output. We next resolve the circular polarization degree of the transmitted light when the nanohole array is excited with linear polarization. We attribute the disbalance of left and right transmitted light to the asymmetry of the nanohole, which we support by numerical simulations. We believe that the optimization of such simple plasmonic geometry could lead to multifunctional flat-optic devices. [ABSTRACT FROM AUTHOR]

Published
2023
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9. Titanium and Silicon Dioxide-Coated Fabrics for Management and Tuning of Infrared Radiation.

Author

Yuce, Ismail, Canoglu, Suat, Yukseloglu, Sevhan Muge, Li Voti, Roberto, Cesarini, Gianmario, Sibilia, Concita, and Larciprete, Maria Cristina

Subjects
ATTENUATED total reflectance, MECHANICAL abrasion, NEAR infrared reflectance spectroscopy, INFRARED radiation, COATED textiles, WEAVING patterns, COATING processes, SCANNING electron microscopy
Abstract

Far infrared radiation (FIR) is emitted by every body at a given temperature, including the human body. FIR ranging between 4–14 μm is considered useful for cell growth, and the human body emits a maximum of infrared (IR) radiation at the wavelength of approximately 9.3 µm. In the present study, fabrics based on five different raw textiles having the same yarn count as well as the same weaving patterns were designed and created. Some of them were subjected to a coating process. The fabrics to be tested were as follows: coated with TiO2 nanoparticles, coated with SiO2 nanoparticles, coated fabric that does not contain bioceramic nanoparticle (BNFC), and non-coated fabrics (NCF). The structural characterization of the resulting samples was performed using scanning electron microscopy (SEM), abrasion tests, and air permeability. Following the structural characterization, the infrared emissivity properties were investigated using infrared thermography as well as attenuated total reflectance Fourier-transform infrared spectroscopy in the 8–14 IR range. According to the experimental findings, the fabrics coated with TiO2 and SiO2 displayed increased infrared emissivity values compared to the uncoated ones. In addition, it was observed that the use of bioceramic powders had no effect on air permeability and abrasion properties. [ABSTRACT FROM AUTHOR]

Published
2022
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10. Extrinsic Chirality and Circular Dichroism at Visible Frequencies Enabled by Birefringent α‑MoO3 Nanoscale-Thick Films: Implications for Chiro-Optical Control.

Author

Petronijevic, Emilija, Dereshgi, Sina Abedini, Larciprete, Maria Cristina, Centini, Marco, Sibilia, Concita, and Aydin, Koray

Abstract

Nanophotonics community has shown great interest in 2D materials because of their unique properties of electromagnetic field manipulation. Many of these materials exhibit strong natural anisotropy, which further opens possibilities of polarization manipulation. Here, we show that α-MoO3, an emerging natural hyperbolic 2D material, can be combined with plasmonic nanostructures to provide strong extrinsic chirality in the visible range. A combination of biaxial anisotropy in α-MoO3 and Fabry–Perot cavities with nanoscale features leads to different absorption of left and right circularly polarized photons, hence exhibiting circular dichroism (CD). Our simulation results predict that multilayer nanoscale-thick films including α-MoO3 are potential candidates for achieving extrinsic chirality across the visible range. Furthermore, we show a significant CD increase when the α-MoO3 layer is coupled with plasmonic nanohole arrays or plasmonic nanocubes. Such designs are achiral in geometry and therefore easier to fabricate. Moreover, we optimize the CD dissymmetry factor gCD for the nanocube-based design at 780 nm, obtaining 84%. We believe that utilizing biaxially anisotropic α-MoO3 films to control and engineer chiro-optical properties in the visible frequency range will open research directions and enable enhanced functionalities in chiro-optical control at the nanoscale, further leading to applications in chiral sensing and CD. [ABSTRACT FROM AUTHOR]

Published
2022
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11. Characterization of Chirality in Diffractive Metasurfaces by Photothermal Deflection Technique.

Author

Li Voti, Roberto, Leahu, Grigore, Petronijevic, Emilija, Belardini, Alessandro, Cesca, Tiziana, Scian, Carlo, Mattei, Giovanni, and Sibilia, Concita

Subjects
CHIRALITY, MIRROR symmetry, CIRCULAR polarization
Abstract

Featured Application: Photothermal characterization of chiro-optical phenomena in metasurfaces. Chirality, a lack of mirror symmetry, is present in nature at all scales; at the nanoscale, it governs the biochemical reactions of many molecules, influencing their pharmacology and toxicity. Chiral substances interact with left and right circularly polarized light differently, but this difference is very minor in natural materials. Specially engineered, nanostructured, periodic materials can enhance the chiro-optical effects if the symmetry in their interactions with circular polarization is broken. In the diffraction range of such metasurfaces, the intensity of diffracted orders depends on the chirality of the input beam. In this work, we combine a photothermal deflection experiment with a novel theoretical framework to reconstruct both the thermal and optical behavior of chiro-optical behavior in diffracted beams. [ABSTRACT FROM AUTHOR]

Published
2022
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12. Fluorescence Spectroscopy of Enantiomeric Amide Compounds Enforced by Chiral Light.

Author

Belardini, Alessandro, Petronijevic, Emilija, Ghahri, Ramin, Rocco, Daniele, Pandolfi, Fabiana, Sibilia, Concita, and Mattiello, Leonardo

Abstract

Featured Application: Fluorescence-detected circular dichroism in novel molecules. Chirality, the absence of mirror symmetry, governs behavior in most biologically important molecules, thus making the chiral recognition of great importance in the pharmaceutical and agrochemical industries, as well as medicine. Chiral molecules can be characterized by means of optical experiments based on chiro-optical excitation of molecules. Specifically, chiral absorptive materials differently absorb left- and right-circular polarized light, i.e., they possess circular dichroism (CD). Unfortunately, the natural CD of most molecules is very low and lies in the ultraviolet range. Fluorescence-detected CD is a fast and sensitive tool for investigation of chiral molecules which emit light; ultralow CD in absorption can be detected as the difference in emission. In this work, we perform fluorescence-detected CD on novel chiral amide compounds, designed specifically for visible green emission; we synthesize two enantiomeric fluorescent compounds using low-cost starting compounds and easy purification. We investigate different solutions of the enantiomers at different concentrations, and we show that the fluorescence of the intrinsically chiral compounds depends on the polarization state of the penetrating light, which is absorbed at 400 nm and emits across the green wavelength range. We believe that these compounds can be coupled with plasmonic nanostructures, which further shows promise in applications regarding chiral sensing or chiral emission. [ABSTRACT FROM AUTHOR]

Published
2021
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13. VO2 Tungsten Doped Film IR Perfect Absorber.

Author

Larciprete, Maria Cristina, Ceneda, Daniele, Scirè, Daniele, Mosca, Mauro, Adorno, Dominique Persano, Dereshgi, Sina Abedini, Aydin, Koray, Macaluso, Roberto, Voti, Roberto Li, Sibilia, Concita, Cesca, Tiziana, Mattei, Giovanni, and Centini, Marco

Subjects
PHYSICS research, PHYSICAL optics, REFLECTANCE, TUNGSTEN, VANADIUM dioxide
Abstract

We investigated infrared reflectivity of undoped and Tungsten (W) doped Vanadium dioxide (VO2) films at varying temperatures. Undoped VO2 exhibited a clear phase transition at 100°C, achieving near 0% reflectivity, or perfect light absorption. As W doping concentration increased, the phase-transition temperature decreased, maintaining the zero-reflectivity condition. Only a 0.75% W doping enabled room temperature perfect absorption without heating the film. [ABSTRACT FROM AUTHOR]

Published
2023
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14. Tuning mid-infrared polarization sensitive reflectivity in GaN/AlGaN heterostructures.

Author

Bile, Alessandro, Centini, Marco, Ceneda, Daniele, Passaseo, Adriana, Tobaldi, David Maria, Tasco, Vittorianna, Sibilia, Concita, and Larciprete, Maria Cristina

Subjects
PHYSICS research, PHYSICAL optics, OPTICAL polarization, HETEROSTRUCTURES, SAPPHIRES
Abstract

We present narrow-band polarization-sensitive reflectance of GaN/AlGaN heterostructures in the mid-infrared range. Experimental measurements performed at 15° angle of incidence show the excitation of a Berreman mode at the interface between GaN and sapphire substrate. A transfer matrix method for anisotropic layers has been used to analyze the obtained results. The contribution of the two-dimensional electron gas at the interfaces of the heterostructures has been included by proper modelization of an effective thin layer. [ABSTRACT FROM AUTHOR]

Published
2023
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15. Extrinsic chirality in metasurfaces: Traditional and unconventional experiments – INVITED.

Author

Petronijevic, Emilija, Belardini, Alessandro, Ram Kumar, Hari Prasath, Leahu, Grigore, Voti, Roberto Li, and Sibilia, Concita

Subjects
PHYSICS research, NANOSTRUCTURED materials, OPTICAL measurements, SPECTROMETRY, SPECTRUM analysis
Abstract

Plasmonic nanostructures with achiral, but asymmetric shapes can exhibit chiro-optical phenomena at the nanoscale, given that the nanostructure-light interaction symmetry is broken. Such behaviour is defined as extrinsic chirality, and it is induced by properly arranging the experimental set-up. We show measurement techniques for extrinsic chirality in low-cost, asymmetric samples with nanostructures organized in metasurfaces. We employ widely tuneable chiro-optical characterization of transmission and reflection, as well as the circular polarization degree of the transmitted signal; near-infrared range (680-1080nm) and oblique incidence allow for the detection of resonant features in extrinsic chirality. Other, unconventional experiments use photo-thermal consequences of chirality governed absorption in metasurfaces. Photo-acoustic spectroscopy directly gives circular dichroism as a differential absorption of the left and right circular polarizations exciting the sample. Photo-deflection spectroscopy gives additional information of diffraction phenomena governed by the extrinsic chirality. We showed that these techniques can monitor the extrinsic chiral behaviour of the hybrid plasmonic metamaterials. Moreover, they can be used in combination with fluorescence-detected circular dichroism to measure the emission properties of fluorescent materials. [ABSTRACT FROM AUTHOR]

Published
2023
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16. Diffracted Beams from Metasurfaces: High Chiral Detectivity by Photothermal Deflection Technique.

Author

Leahu, Grigore, Petronijevic, Emilija, Li Voti, Roberto, Belardini, Alessandro, Cesca, Tiziana, Mattei, Giovanni, and Sibilia, Concita

Subjects
OPTICAL measurements, CIRCULAR dichroism, DEFLECTION (Mechanics), CIRCULAR polarization, UNIT cell, CHIRALITY, MIRRORS
Abstract

Measurements of difference in optical interactions between circularly polarized excitations of opposite handedness (circular dichroism) are highly important for both natural and artificial chiral structures. Here the photothermal deflection technique is proposed as a method to detect the optical chirality of a metasurface, analyzing the diffracted beams by the metasurface itself. Two metasurfaces are investigated, based on Au and Ag. The samples are fabricated by nanosphere lithography, with a tilted deposition of thin metal layer, which produces symmetry‐breaking. The unit cell periodicity of these metasurfaces allows for multiple order diffraction in the 450–520 nm range, which encompasses the emission lines of an Ar laser. The metasurfaces are placed on a mirror and excited by an Ar pump beam at different orientations, laser wavelengths, and circular polarization degree; the probe beam scans the absorption of the diffraction orders back‐reflected from the underlying mirror. In this way, the chiral investigation is simplified by placing the scanning of absorption‐induced thermal effect into the metasurface plane, thus avoiding the transmission/reflection measurements of a specific order, which are done by angular placement of detector. Theoretical and numerical approaches are further developed to reconstruct both thermal and optical behavior of the chirality at the nanoscale. [ABSTRACT FROM AUTHOR]

Published
2021
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18. Plasmonic Elliptical Nanohole Arrays for Chiral Absorption and Emission in the Near-Infrared and Visible Range.

Author

Petronijevic, Emilija, Ghahri, Ramin, and Sibilia, Concita

Subjects
FIELD emission, CIRCULAR polarization, PLANE wavefronts, POLARITONS, INFRARED absorption, CHIRALITY
Abstract

Featured Application: Plasmonic elliptical nanohole arrays coupled with emitting layers for near-infrared and visible chiral sources. Chiral plasmonic nanostructures with tunable handedness-dependent absorption in the visible and infrared offer chiro-optical control at the nanoscale. Moreover, coupling them with emitting layers could lead to chiral nanosources, important for nanophotonic circuits. Here, we propose plasmonic elliptical nanohole arrays (ENHA) for circularly dependent near-infrared and visible emission. We first investigate broadband chiral behavior in an Au-ENHA embedded in glass by exciting it with plane waves. We then study the coupling of ENHA with a thin emitting layer embedded in glass; we focus on the emission wavelengths which provided high chirality in plane-wave simulations. Our novel simulation set-up monitors the chirality of the far-field emission by properly averaging a large set of homogeneously distributed, randomly oriented quantum sources. The intrinsic chirality of ENHA influences the circular polarization degree of the emitting layer. Finally, we study the emission dependence on the field distribution at the excitation wavelength. We demonstrate the chiral absorption and emission properties for Au-ENHA emitting in the near-infrared range, and for Ag-ENHA which is excited in green range and emits in the Lumogen Red range. The simple geometry of ENHA can be fabricated with low-cost nanosphere lithography and be covered with emission gel. We thus believe that this design can be of great importance for tunable chiral nanosources. [ABSTRACT FROM AUTHOR]

Published
2021
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19. Broadband optical spin dependent reflection in self-assembled GaAs-based nanowires asymmetrically hybridized with Au.

Author

Petronijevic, Emilija, Belardini, Alessandro, Leahu, Grigore, Hakkarainen, Teemu, Piton, Marcelo Rizzo, Koivusalo, Eero, and Sibilia, Concita

Subjects
NANOWIRES, SEMICONDUCTOR nanocrystals, LITHOGRAPHY, WAVELENGTHS, SUBSTRATES (Materials science)
Abstract

Hybridization of semiconductor nanostructures with asymmetric metallic layers offers new paths to circular polarization control and chiral properties. Here we study, both experimentally and numerically, chiral properties of GaAs-based nanowires (NWs) which have two out of six sidewalls covered by Au. Sparse ensembles of vertical, free-standing NWs were fabricated by means of lithography-free self-assembled technique on Si substrates and subsequently covered by Au using tilted evaporation. We report on optical spin-dependent specular reflection in the 680–1000 nm spectral range when the orientation of the golden layers follows the rule of extrinsic chirality. The analysis shows reflection peaks of the chiral medium whose intensity is dependent on the light handedness. We further propose a novel, time-efficient numerical method that enables a better insight into the far-field intensity and distribution of the scattered light from a sparse NW ensembles. The measurements done on three different samples in various orientations show good agreement with theoretical predictions over a broad wavelength range. [ABSTRACT FROM AUTHOR]

Published
2021
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20. New Self‐Organization Route to Tunable Narrowband Optical Filters and Polarizers Demonstrated with ZnO–ZnWO4 Eutectic Composite.

Author

Osewski, Paweł, Belardini, Alessandro, Centini, Marco, Valagiannopoulos, Constantinos, Leahu, Grigore, Li Voti, Roberto, Tomczyk, Monika, Alù, Andrea, Pawlak, Dorota A., and Sibilia, Concita

Subjects
LIGHT filters, ELECTROMAGNETIC fields, COMPOSITE materials, BANDPASS filters, OPTICAL properties, ZINC oxide synthesis, ZINC oxide
Abstract

Electromagnetic fields interacting with microscopic structural features in a composite material provide emerging optical properties that surpass those offered by the individual components. However, composite materials can be generally lossy due to the scattering effects induced by inhomogeneities at the interfaces between different compounds. To overcome such problems, complicated and costly manufacturing procedures, such as top‐down approaches, are generally required. In contrast, here ZnO–ZnWO4 eutectic self‐organized composites grown by the micropulling method are considered, displaying sharp and strongly polarized transmission at 397 nm. Such an optical response is notable because it is not observed in either ZnO or ZnWO4 single crystals. The optical response is due to the refractive index matching of the two constituents, which self‐organize into ordered structures via a micropulling down method. The optical behavior reported here can directly lead to applications, such as tunable narrowband filters with bandpass of 3 nm and polarizers, paving the way to a new self‐organization route for manufacturing optical components. [ABSTRACT FROM AUTHOR]

Published
2020
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21. Circular Dichroism in Low-Cost Plasmonics: 2D Arrays of Nanoholes in Silver.

Author

Petronijevic, Emilija, Belardini, Alessandro, Leahu, Grigore, Cesca, Tiziana, Scian, Carlo, Mattei, Giovanni, and Sibilia, Concita

Subjects
CIRCULAR polarization, SILVER, CIRCULAR dichroism, NUMERICAL analysis, CHIRALITY, PLASMONICS, HANDEDNESS
Abstract

Featured Application: chirality, plasmonics, enantioselectivity. Arrays of nanoholes in metal are important plasmonic devices, proposed for applications spanning from biosensing to communications. In this work, we show that in such arrays the symmetry can be broken by means of the elliptical shape of the nanoholes, combined with the in-plane tilt of the ellipse axes away from the array symmetry lines. The array then differently interacts with circular polarizations of opposite handedness at normal incidence, i.e., it becomes intrinsically chiral. The measure of this difference is called circular dichroism (CD). The nanosphere lithography combined with tilted silver evaporation was employed as a low-cost fabrication technique. In this paper, we demonstrate intrinsic chirality and CD by measuring the extinction in the near-infrared range. We further employ numerical analysis to visualize the circular polarization coupling with the nanostructure. We find a good agreement between simulations and the experiment, meaning that the optimization can be used to further increase CD. [ABSTRACT FROM AUTHOR]

Published
2020
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28. Asymmetric and tunable infrared emission in metamaterials composed by oriented air voids into a polar material.

Author

Larciprete, Maria Cristina, Centini, Marco, Li Voti, Roberto, and Sibilia, Concita

Subjects
WAVELENGTHS, SILICON carbide, EMISSIVITY, ELECTRIC fields, ELECTRONIC excitation
Abstract

We numerically investigated the asymmetric spectral emissivity in the mid- to long-infrared range of a metamaterial composed by subwavelength oriented air inclusions into a polar (SiC) matrix. The longitudinal phononic resonance can be excited and tuned as a function of the inclusions content and orientation, within the application limits of the effective medium homogenization technique. Furthermore, our numerical results show that it is possible to enhance the emissivity in a given direction rather than in the opposite one by continuously varying the inclusions filling factor along the film thickness. As an example, we design a graded air inclusion pattern starting from a few microns thick SiC layer. We show that a strongly asymmetric (forward vs. backward) emission along the normal direction to the surface can be achieved. [ABSTRACT FROM AUTHOR]

Published
2019
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30. Experiments and simulations of chiro-optical response in lowcost nanohole arrays in silver.

Author

Petronijevic, Emilija, El-ansary, Zakaria, Brioual, Bilal, Belardini, Alessandro, Prasath Ram Kumar, Hari, Cesca, Tiziana, Scian, Carlo, Mattei, Giovanni, and Sibilia, Concita

Subjects
PLASMONICS, BIOSENSORS, LITHOGRAPHY, CIRCULAR polarization, LIGHT transmission
Abstract

2D metasurfaces based on periodic nanoholes in metal have been proposed in various plasmonic platforms. Specifically, their resonant features have led to applications spanning in biosensing. Here we investigate additional degree of freedom in elliptical nanohole arrays with hexagonal geometry: chiro-optical effects. Namely, the in-plane asymmetry and a slightly elliptical shape of nanoholes were previously shown to differently extinct light of opposite handedness, even at normal incidence. We now fully characterize nanoholes in Ag, fabricated by low-cost nanosphere lithography. We first measure the dependence of the transmitted intensity for opposite handedness, in a broad spectral and angle of incidence range. We then resolve the circular polarization degree of the transmitted light when the nanohole array is excited with linear polarization. Finally, we numerically investigate the origin of the chiro-optical effect at the nanoscale. We believe that circular polarization resolving of the transmitted degree could be further adapted as a highly sensitive tool in chiral sensing. [ABSTRACT FROM AUTHOR]

Published
2022
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31. Characterization of output circular polarization degree in lowcost asymmetric metasurfaces.

Author

Petronijevic, Emilija, Belardini, Alessandro, El-ansary, Zakaria, Brioual, Bilal, Prasath Ram Kumar, Hari, Cesca, Tiziana, Scian, Carlo, Mattei, Giovanni, and Sibilia, Concita

Subjects
CIRCULAR polarization, PLASMONICS, NANOSTRUCTURED materials, POLYSTYRENE, CHIRALITY
Abstract

Addition of asymmetry in plasmonic nanostructures can lead to chiro-optical phenomena, usually monitored as different absorption of left and right polarization, i.e. circular dichroism. Moreover, interesting features arise when the nanostructure changes the polarization state of the input beam. In this work, we perform extrinsic chirality characterization in a widely tuneable near-infrared range, by monitoring both polarization of the input and of the transmitted beam. We characterize low-cost metasurfaces based on polystyrene nanospheres asymmetrically covered by Ag, by exciting them at different angle of incidence with left, right and linear polarization. We then resolve the circular polarization degree of the transmitted beam, demonstrating resonance-governed circular polarization degree in the output, showing the interplay of both intrinsic and extrinsic chirality. [ABSTRACT FROM AUTHOR]

Published
2022
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32. Mid-infrared narrowband polarization management with Al doped ZnO-ZnWO4 eutectic composites.

Author

Centini, Marco, Larciprete, Maria Cristina, Sibilia, Concita, and Pawlak, Dorota. A.

Subjects
PHOTONICS, ZINC oxide, EUTECTICS, BIOMOLECULES, REFLECTANCE
Abstract

We report a narrowband polarization-dependent reflectivity from Al-doped ZnO/ZnWO4 self-assembled eutectic composites in the mid-infrared range. Our results show a reflectivity modulation from 0.05 to 0.75 for two orthogonal polarizations of the incident field with a 10% Al concentration. Acting as natural polarizing filters these eutectic composites could open the way to the future development of low-cost photonics components in the IR. [ABSTRACT FROM AUTHOR]

Published
2022
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37. Optical and photoacoustic investigation of AZO/Ag/AZO transparent conductive coating for solar cells.

Author

Cesarini, Gianmario, Leahu, Grigore, Grilli, Maria Luisa, Sytchkova, Anna, Sibilia, Concita, and Li Voti, Roberto

Subjects
SOLAR cells, INDIUM tin oxide, ELECTRIC conductivity, DIRECT energy conversion, PHOTOACOUSTIC spectroscopy
Abstract

Great attention has been recently paid to transparent conductive oxides (TCOs) due to their application in optoelectronic devices, flat panel displays, solar cells, and anti-static coatings. Concerning photovoltaic applications, the reduction of the material and processing costs are the key factors in the production process. Due to In scarcity and cost, alternative solutions to indium tin oxide (ITO) are needed. Al-doped ZnO (AZO) meets the requirements for application in thin film solar cells, thanks to its good optoelectrical properties, low cost and higher resistance to Hydrogen-reach plasmas. Recently many papers analyze innovative AZO based TCO structures where a thin layer of Silver is introduced in the TCO so to increase the electrical conductivity without loosing transparency. In this work we study the transparency and the electrical sheet resistance of a multilayer AZO/Ag/AZO as a function of the silver thin layer, and discuss the problem of optimizing the thicknesses of the multilayers to get the best performances. We have realized an AZO/Ag/AZO multilayer coating by radio frequency (RF) sputtering with an optimal thickness of the silver layer. Optical and photoacoustic spectroscopy (PAS) have been applied to perform the characterization of the sample. In particular PAS seems the most efficient technique to test directly the absorbance of the structure which should be reduced to avoid overheating and loss of the solar cell efficiency. [ABSTRACT FROM AUTHOR]

Published
2016
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38. Preface.

Author

Sibilia, Concita, Belardini, Alessandro, and Pauliat, Gilles

Subjects
OPTICAL communications, PHOTONICS, POSTER presentations
Published
2021
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41. Second harmonic generation on self-assembled tilted gold nanowires.

Author

Belardini, Alessandro, Centini, Marco, Leahu, Grigore, Fazio, Eugenio, Sibilia, Concita, Haus, Joseph W., and Sarangan, Andrew

Abstract

Here we present measurements on a metasurface composed by tilted gold nanowires. The metasurface can induce an optical chiral response of the whole sample when the light impinges on the sample out of the normal incidence angle. In order to investigate the symmetry breaking induced by the geometry, we measured the second harmonic generation (SHG) signal generated by circular polarized pulsed light. This technique has demonstrated to be a powerful method in order to investigate the chiral morphology of nanostructures. [ABSTRACT FROM AUTHOR]

Published
2015
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