Elena Velichko scite author profile

We apply the Lifshitz theory of dispersion forces to find a contribution to the free energy of peptide films which is caused by the zero-point and thermal fluctuations of the electromagnetic field.For this purpose, using available information about the imaginary parts of dielectric permittivity of peptides, the analytic representation for permittivity of typical peptide along the imaginary frequency axis is devised. Numerical computations of the fluctuation-induced free energy are performed at room temperature for the freestanding peptide films, containing different fractions of water, and for similar films deposited on dielectric (SiO 2 ) and (Au) substrates. It is shown that the free energy of a freestanding peptide film is negative and, thus, contributes to its stability.The magnitude of the free energy increases with increasing fraction of water and decreases with increasing thickness of a film. For peptide films deposited on a dielectric substrate the free energy is nonmonotonous. It is negative for thicker than 100 nm films, reaches the maximum value at some film thickness, but vanishes and changes its sign for thinner than 100 nm films. The fluctuation-induced free energy of peptide films deposited on metallic substrate is found to be positive which makes films less stable. In all three cases, simple analytic expressions for the free energy of sufficiently thick films are found. The obtained results may be useful to attain film stability in the next generation of organic microdevices with further shrinked dimensions.

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Texture appearance model, a new model-based segmentation paradigm, application on the segmentation of lung nodule in the CT scan of the chest

Shariaty

Orooji

Velichko

et al. 2022

Computers in Biology and Medicine

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Characterization of Magnetite–Silica Magnetic Fluids by Laser Scattering

et al. 2020

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The paper is concerned with structural, morphological and magnetic properties of magnetite-silica magnetic fluids. The granulometric composition of the magnetic fluids was investigated by scanning and transmission electron microscopy, the phase composition was studied by X-ray diffraction and reflection high-energy electron diffraction, and magnetic properties were studied by vibrating sample magnetometry. In order to reveal the particle size distribution, dynamic light scattering and a proposed modification of depolarized dynamic light scattering were employed. The shape and dimensions of magnetic nanoparticles and also their aggregates are described. While the aspect ratio for the aggregates was 0.5–0.99, individual nanoparticles had an average aspect ratio of 0.9 and were nearly spherical. The sedimentation stability of a diluted magnetic fluid was also investigated. When the fluids were diluted 200 times, the stability was partially lost, and the nanoparticles aggregated, thereby forming clusters, and precipitated.

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Fiber-optic system for simulating accidents in the cooling circuits of a nuclear power plant

et al. 2015

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The Performance of Active-Contour and Region Growing Methods Against Noises in the Segmentation of Computed-Tomography Scans

Mousavi

Shariaty

Orooji

et al. 2020

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Methods of non-destructive testing in studies of self-organization processes in protein films

Baranov

Velichko

Aksenov

2017

J. Phys.: Conf. Ser.

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Molecular Aggregation in Immune System Activation Studied by Dynamic Light Scattering

Velichko

Makarov

Nepomnyashchaya

2020

Biology

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Determination of the concentration and size of the circulating immune complexes in the blood is an essential part of diagnostics of immune diseases. In this work, we suggest using the dynamic light scattering method to determine the sizes of circulating immune complexes in blood serum. By the dynamic light scattering spectrometer, we found that for healthy and sick donors, the size and concentration of circulating immune complexes differed significantly. The dynamics of formation of these complexes were also examined in this work. It was shown that the formation of immune complexes in the blood of healthy donors is faster than the same reactions in the blood serum of donors with diseases. The results can be used in the diagnostics of the immune status and detection of chronic inflammation. We can recommend the dynamic light scattering method for implementation in biomedical diagnostics.

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Elena Velichko

A Nutation Nuclear-Magnetic Teslameter for Measuring Weak Magnetic Fields

Fluctuation-induced free energy of thin peptide films

Texture appearance model, a new model-based segmentation paradigm, application on the segmentation of lung nodule in the CT scan of the chest

Characterization of Magnetite–Silica Magnetic Fluids by Laser Scattering

Fiber-optic system for simulating accidents in the cooling circuits of a nuclear power plant

The Performance of Active-Contour and Region Growing Methods Against Noises in the Segmentation of Computed-Tomography Scans

Methods of non-destructive testing in studies of self-organization processes in protein films

Molecular Aggregation in Immune System Activation Studied by Dynamic Light Scattering

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