Michal Lesňák scite author profile

Abstract:We present a white-light spectral interferometric technique for measuring the absolute spectral optical path difference (OPD) between the beams in a slightly dispersive Michelson interferometer with a thin-film structure as a mirror. We record two spectral interferograms to obtain the spectral interference signal and retrieve from it the spectral phase, which includes the effect of a cube beam splitter and the phase change on reflection from the thin-film structure. Knowing the effective thickness and dispersion of the beam splitter made of BK7 optical glass, we use a simple procedure to determine both the absolute spectral phase difference and OPD. The spectral OPD is measured for a uniform SiO 2 thin film on a silicon wafer and is fitted to the theoretical spectral OPD to obtain the thin-film thickness. The theoretical spectral OPD is determined provided that the optical constants of the thin-film structure are known. We measure also the nonlinear-like spectral phase and fit it to the theoretical values in order to obtain the thin-film thickness.

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Thickness of SiO2 thin film on silicon wafer measured by dispersive white-light spectral interferometry

Hlubina

Ciprián

Luňáček

et al. 2006

Appl. Phys. B

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Physical properties of Al doped Ba hexagonal ferrite thin films

Harward

Nie

Chen

et al. 2013

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We developed the thin film microwave magnetic material, M-type barium hexagonal ferrite (BaM) doped with Al, for signal processing devices operating above 40 GHz with little to no applied magnetic field. Al was chosen as the dopant material because it significantly increases the already strong anisotropy field of BaM. A series of thin film BaAlxFe12-xO19 samples, x ranging from 0 to 2 in 0.25 steps, were deposited on Pt templates using a metal-organic decomposition growth technique. The resulting films are polycrystalline and highly textured, with the hexagonal c-axis directed out of plane. These films are also self-biasing; easy axis hysteresis loops have a high squareness ratio, s, in the 0.83-0.92 range. As expected, the anisotropy field increases with x, ranging from 1.34 to 2.19 × 106 A/m (16.9-27.5 kOe) for x = 0-2, while the saturation magnetization Ms decreases with x, ranging from 0.334 to 0.175 × 106 A/m (4πMs = 4.2-2.2 kG) for x = 0-2. These values were measured at room temperature, but the temperature dependence of these quantities was also measured below room temperature, down to 30 K. The measured ferromagnetic resonance linewidths, on the order of 12-30 × 103 A/m (140–370 Oe) for compositions below x = 1, indicate device-quality films. Above a certain threshold, the linewidth increases linearly with frequency at a rate of 0.2-0.64 × 103 (A/m)/GHz (2.5-8 Oe/GHz) for x = 0–1, respectively. The behavior of the linewidth is correlated with the structural properties of the films measured using x-ray diffraction and atomic force microscopy. The results of magnetic force microscopy, Curie point measurements, spectral ellipsometry (index of refraction), and magneto-optical measurements are also included and discussed.

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Design of Plasmonic-Waveguiding Structures for Sensor Applications

2019

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Surface plasmon resonance has become a widely accepted optical technique for studying biological and chemical interactions. Among others, detecting small changes in analyte concentration in complex solutions remains challenging, e.g., because of the need of distinguishing the interaction of interest from other effects. In our model study, the resolution ability of plasmonic sensing element was enhanced by two ways. Besides an implementation of metal-insulator-metal (MIM) plasmonic nanostructure, we suggest concatenation with waveguiding substructure to achieve mutual coupling of surface plasmon polariton (SPP) with an optical waveguiding mode. The dependence of coupling conditions on the multilayer parameters was analyzed to obtain optimal field intensity enhancement.

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Experimental Implementation of New Technology into the Area of Teaching Occupational Safety for Industry 4.0

Laciok¹,

Bernatík²,

Lesňák³

2020

IJSSE

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The use of new technologies (additive technology, collaborative robotics, virtual or augmented reality) in teaching and preparing for it gives the teacher many different ways to activate students to learn. Therefore, this article focuses on the options for using virtual reality in the field of occupational safety. A work injury scenario was created in the XVR software environment. It was aimed at students studying Occupational and Process Safety at the Faculty of Safety Engineering (FSE), VSB-Technical University of Ostrava. In the future, they will be professionally qualified in risk prevention (Health, Safety, Environment Professional, HSE). The aim was to train students in: an employer's obligations during a work injury, the HSE Professional's job during a work injury, cooperating with the emergency services and the Czech Police.

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Michal Lesňák

Dispersive white-light spectral interferometry with absolute phase retrieval to measure thin film

Thickness of SiO2 thin film on silicon wafer measured by dispersive white-light spectral interferometry

Physical properties of Al doped Ba hexagonal ferrite thin films

Design of Plasmonic-Waveguiding Structures for Sensor Applications

Experimental Implementation of New Technology into the Area of Teaching Occupational Safety for Industry 4.0

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