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16 results on '"M Kalita"'

1. Spontaneous change of symmetry in a magnetoactive elastomer beam at its critical bending induced by a magnetic field

Author

V M Kalita, Yu I Dzhezherya, S V Cherepov, Yu B Skirta, A V Bodnaruk, and S M Ryabchenko

Subjects
Mechanics of Materials, Signal Processing, General Materials Science, Electrical and Electronic Engineering, Condensed Matter Physics, Atomic and Molecular Physics, and Optics, Civil and Structural Engineering
Abstract

The features of the critical bending deformation and magnetization of a magnetoactive elastomer (MAE) beam with a fixed end in a transverse uniform magnetic field have been studied. After the beam reaches a critical bending, the symmetry of the beam shape and the symmetry of the MAE magnetic state change spontaneously. At the critical point, a continuous transition from the highly symmetric magnetic state in the unbent MAE beam to the low symmetric magnetic state in the bent MAE beam (this is the angular state with the effective magnetization inclined to the field) takes place. The beam bending occurs due to the gain in the magnetic energy of the beam. The formation of an angular magnetic state in it has a magnetoelastic origin and is characterized by the critical behavior of the mutually related bending and longitudinal effective magnetization of the MAE, but it is the magnetization that plays the role of order parameter. Furthermore, there is no longitudinal magnetization in the absence of bending and, vice versa, there is no bending in the absence of longitudinal magnetization. The influence of a low remanent magnetization, which eliminates the uncertainty in the bending direction, on the critical bending has been analyzed. The role of the magnetorheological effect, which affects the critical field magnitude and leads to the appearance of field-induced bending hysteresis near the critical point, has also been elucidated.

Published
2023

2. Critical bending and shape memory effect in magnetoactive elastomers

Author

Yu. B. Skirta, Georgiy Levchenko, S. V. Cherepov, A.V. Bodnaruk, Yu. I. Dzhezherya, and V. M. Kalita

Subjects
Materials science, Mechanics of Materials, Signal Processing, General Materials Science, Shape-memory alloy, Bending, Electrical and Electronic Engineering, Composite material, Condensed Matter Physics, Elastomer, Smart material, Atomic and Molecular Physics, and Optics, Civil and Structural Engineering
Abstract

The results of a study of magnetoactive elastomers (MAEs) consisting of an elastomer matrix with embedded ferromagnetic particles are presented. A continuous critical bending induced by the magnetic field, characterized by a critical exponent for the bending magnitude, and the derivative of which has a singularity in the critical region is reported for the first time. The mechanical stability loss and the symmetry reduction of the magnetic state, which are interrelated with each other, take place at the critical point. The magnetization in the high-symmetric state (below the critical point) is directed along the magnetic field and the torque is absent. Above the critical point, the magnetization and the magnetic field are noncollinear and there arises a torque, which is self-consistent with the bending. The magnetic field dependence of the MAE bending was found to have a hysteresis, which is associated with the magneto-rheological effect. The shape memory effect was also obtained for the MAE bending in a cycle consisting of magnetization, cooling (at H ≠ 0), and heating (at H = 0). The influence of the critical glass transition temperature of the matrix, as well as its melting/solidification temperature, on the magnetic shape memory effect was studied.

Published
2021

3. The average value of the spin squared operator as an order parameter for spin phase transitions without spontaneous lowering of symmetry

Author

V. M. Kalita and Georgiy Levchenko

Subjects
Phase transition, Materials science, Quantum mechanics, Operator (physics), General Physics and Astronomy, Order (group theory), Value (computer science), Condensed Matter::Strongly Correlated Electrons, Symmetry (physics), Spin-½
Abstract

Phase transitions from the low-spin to the high-spin state are a unique physical phenomenon without lowering of symmetry. In contrast to magnetic phase transitions, for which vector or tensor of physical quantities are used as order parameters, we have shown that for spin phase transitions the order parameter is a scalar quantity—the thermodynamic mean of spin square operator, which was not previously used at all in the theory of phase transitions. The free energy in the form of a functional of this order parameter is determined, and the phase diagrams for spin transitions are constructed. The influence of the pressure on spin transition is analyzed also. It is shown that the spin Hamiltonian with this order parameter allows one to obtain all possible spin transformations in compounds. At the same time, this order parameter correctly reflects the physical nature of the spin transition phenomena.

Published
2020

4. Critical behavior of ensembles of superparamagnetic nanoparticles with dispersions of magnetic parameters

Author

V. M. Kalita, Anatolii Belous, S. M. Ryabchenko, A.V. Bodnaruk, M. M. Kulyk, Sergii Solopan, and Alexandr Tovstolytkin

Subjects
Materials science, Condensed matter physics, Nanoparticle, 02 engineering and technology, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 01 natural sciences, Condensed Matter::Materials Science, Paramagnetism, Magnetization, 0103 physical sciences, Magnetic nanoparticles, Curie temperature, General Materials Science, 010306 general physics, 0210 nano-technology, Dispersion (chemistry), Spontaneous magnetization, Superparamagnetism
Abstract

Different processes governing magnetic properties of an ensemble of magnetic nanoparticles in the temperature region close to a transition from superparamagnetic to paramagnetic state are analyzed and the ways to separate them are suggested. Enhanced role of paraprocess in magnetization behavior near Curie temperature is stressed. A procedure to isolate paraprocess contribution and adequately determine spontaneous magnetization of the ensemble of superparamagnetic nanoparticles is proposed. Critical behavior of the spontaneous magnetization is experimentally determined for the ensemble of nanoparticles of lanthanum-strontium manganites, which are considered as promising materials for self-controlled magnetic nanohyperthermia. Effect of dispersion of magnetic parameters on effective magnetic characteristics of nanoparticles and their critical behavior is discussed. Theoretical background for the use of the 'effective Curie temperature for the ensemble of nanoparticles' concept is proposed for ensembles of particles with dispersion of their Curie temperature. Based on the results obtained, various strategies to develop novel biomedical applications, in particular those suitable for noninvasive temperature monitoring, are discussed.

Published
2019

5. Analysis of fraction distribution of the water drops stream generated by the spraying nozzles of new KOMAG design

Author

M. Kalita, D. Bałaga, and M. Siegmund

Subjects
Distribution (number theory), Nozzle, Environmental science, Fraction (chemistry), Mechanics
Abstract

Theoretical backgrounds of airborne dust control with use of atomized stream of liquid are presented. Testing procedure, with a special attention paid to analysis of drops fraction distribution, is presented on the example of new nozzle design developed at KOMAG. The method for calculation of absorption surface is discussed. The test results are used to analyse operational parameters of the nozzle which are important for the dust control systems.

Published
2019

6. Magnetic properties and anisotropic coercivity in nanogranular films of Co/Al2O3above the percolation limit

Author

M. M. Kulyk, O. V. Stognei, Vladislav Korenivski, A. F. Lozenko, A. V. Sitnikov, S. M. Ryabchenko, and V. M. Kalita

Subjects
Materials science, Acoustics and Ultrasonics, Condensed matter physics, Magnetism, Film plane, Coercivity, Condensed Matter Physics, Ferromagnetic resonance, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, Condensed Matter::Materials Science, Magnetization, Ferromagnetism, Condensed Matter::Superconductivity, Percolation, Anisotropy
Abstract

Magnetic properties of nanogranular ferromagnetic Co/Al2O3 films with 74.5 at% Co, which is above the percolation limit, are investigated. It is established that the films have perpendicular magnetic anisotropy and a weaker in-plane anisotropy. The magnetization curves show that the film consists of two magnetic components: a dominating contribution from magneto-anisotropic isolated grains with the anisotropy axis perpendicular to the film plane and a weaker contribution from the percolated part of the film. This two-component magnetic composition of the films, with the dominating contribution from the nanograins, is confirmed by transmission electron microscopy as well as by ferromagnetic resonance spectroscopy. It is further established that the coercive field of the film is almost entirely determined by the percolated part of the film. In this, the angular dependence of the coercive force, H-c(theta(H)), is essentially proportional to sin(-1)theta(H), where theta(H) is the angle between the applied field and the film's normal. However, for theta(H) -> 0, H-c(theta(H)) there is a narrow minimum with H-c approaching zero. Such non-linear dependence agrees well with our modelling results for a two-component magnetic system of the film, where the non-percolated nanograins have a distinct perpendicular anisotropy. The reported results should be important for in-depth characterization and understanding the magnetism and anisotropy in inhomogeneous systems as well as for applications, specifically in perpendicular magnetic recording.

Published
2014

7. Rotatable magnetic anisotropy in Si/SiO2/(Co2Fe)xGe1−xHeusler alloy films

Author

V. V. Nevdacha, S. M. Ryabchenko, A. F. Kravets, D. Y. Podyalovskiy, A.Ya. Vovk, V. M. Kalita, M. M. Kulik, Vladislav Korenivski, Maria Helena Godinho, A. F. Lozenko, R. P. Borges, and A. N. Pogorily

Subjects
Models, Molecular, Materials science, Condensed matter physics, Isotropy, Membranes, Artificial, Condensed Matter Physics, Ferromagnetic resonance, Amorphous solid, Condensed Matter::Materials Science, Magnetization, Magnetic anisotropy, Magnetic Fields, Models, Chemical, Metals, Sputtering, Condensed Matter::Superconductivity, Alloys, Anisotropy, Computer Simulation, General Materials Science, Crystallite
Abstract

Polycrystalline (Co2Fe)(x)Ge(1-x) Heusler alloy films are fabricated by sputtering on amorphous substrates and shown to possess three types of magnetic anisotropy. The nearly stoichiometric composition of x = 50 m.f.% shows a rectangular hysteresis loop and isotropic coercive and ferromagnetic resonance fields when the film is field-magnetized along any in-plane direction, thus predominantly possessing rotatable in-plane magnetic anisotropy. Higher-x compositions show evidence of two- and fourfold in-plane anisotropy superposed on the rotatable one. A qualitative model of the observed anisotropic magnetic properties is proposed. The model explains the rotatable anisotropy by taking into account dry friction for the in-plane rotation of the magnetization direction in a fine-grained polycrystalline film with the magnetic grain size smaller than the correlation length of the inter-grain exchange interaction. The observed two- and fourfold magnetic anisotropy contributions are attributed to partial texturing of the fine-grained films, even though the films are grown on amorphous SiO2 substrates. These results should be valuable for understanding and controlling the magnetic behaviour of highly spin-polarized Heusler alloy films used in various magnetic nanodevices.

Published
2013

8. Anomalous behavior of bending deformation induced by a magnetic field in a system of ferromagnetic stripes located on an elastomer.

Author

Yu I Dzhezherya, V M Kalita, S V Cherepov, Yu B Skirta, L V Berezhnaya, and G G Levchenko

Abstract

The effect of anomalous bending in a system of magnetically soft ferromagnetic stripes located on a highly elastic plate of elastomer has been studied both experimentally and theoretically. It was found that the magnetic-field dependences for the bending of plates with ferromagnetic stripes have a critical character with a reproduced hysteresis emerging in the repeated cycles of the magnetic field increasing and decreasing. It was found that the magnetically induced bending has a large magnitude, so that the magnetic moments of the stripes at the bending can be directed almost perpendicularly to the magnetic field. In a strong magnetic field, the effect of stripe orientation is observed, which occurs due to the orienting action of Zeeman interaction. It was shown that the hysteresis phenomenon observed at the bending of a plate with stripes is associated with a strong nonlinearity of magnetostatic interaction between the stripes at their magnetization. The hysteresis recurrence is caused by elastic forces arising at the elastomer bending and competing with magnetostatic dipole–dipole interactions between the stripes. The critical points of transitions between the ‘discrete lattice’ state of stripes and the state of laterally touching stripes were determined. A model of the phenomenon concerned was proposed which is in good agreement with experimental data. [ABSTRACT FROM AUTHOR]

Published
2019
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14. X-Ray Radiation Sensing Properties of ZnS Thin Film: A Study on the Effect of Annealing.

Author

M P Sarma, J M Kalita, and G Wary

Subjects
*STRUCTURAL analysis (Engineering), *IRRADIATION, *ULTRAVIOLET radiation, *CRYSTALLINITY, *X-ray diffraction
Abstract

Chemically synthesized ZnS thin film is found to be a good x-ray radiation sensor. We report the effect of annealing on the x-ray radiation detection sensitivity of a ZnS thin film synthesized by a chemical bath deposition technique. The chemically synthesized ZnS films are annealed at 333, 363 and 393 K for 1 h. Structural analyses show that the lattice defects in the films decrease with annealing. Further, the band gap is also found to decrease from 3.38 to 3.21 eV after annealing at 393 K. Current-voltage characteristics of the films are studied under dark and x-ray irradiation conditions. Due to the decrease of lattice defects and band gap, the conductivity under dark conditions is found to increase fromto , while that under x-ray irradiation increases fromto . On the other hand, the x-ray radiation detection sensitivity of the films is found to decrease with annealing. This decrease of detection sensitivity is attributed to the decrease of the band gap as well as some structural and surface morphological changes occurring after annealing. [ABSTRACT FROM AUTHOR]

Published
2017
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