I. E. Kononova scite author profile

Colloidal particles consisted of individual nanosized magnetite grains on the surface of the silica cores were obtained by two-stage sol-gel technique. Size distribution and microstructure of the particles were analyzed using atomic force microscopy, X-ray diffraction and Nitrogen thermal desorption. Magnetic properties of the particles were studied by the method of the longitudinal nonlinear response. It has been shown that nanoparticles of magnetite have a size corresponding to a superparamagnetic state but exhibit hysteresis properties. The phenomenon was explained using the magnetostatic interaction model based on the hypothesis of iron oxide particles cluster aggregation on the silica surface.

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Fractal-Percolation Structure Architectonics in Sol-Gel Synthesis

Kononova

Kononov

Мошников

et al. 2021

IJMS

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It was developed a new technique to assess micro- and mesopores with sizes below a few nanometers. The porous materials with hierarchical fractal-percolation structure were obtained with the sol-gel method. The tetraethoxysilane hydrolysis and polycondensation reactions were performed in the presence of salts as the sources of metal oxides. The porous materials were obtained under spinodal decomposition conditions during application of the polymer sol to the substrate surface and thermal treatment of the structures. The model is based on an enhanced Kepler net of the 4612 type with hexagonal cells filled with a quasi-two-dimensional projection of the Jullien fractal after the 2nd iteration. The materials obtained with the sol-gel method were studied using the atomic force microscopy, electron microscopy, thermal desorption, as well as an AutoCAD 2022 computer simulation of the percolation transition in a two-component system using the proposed multimodal model. Based on the results obtained, a new method was suggested to assess micro- and mesopores with sizes below a few nanometrs, which cannot be analyzed using the atomic force microscopy and electron microscopy.

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Enhancement of Fluorescence of Nanosized ZnO: SiO2 Films in the Presence of Human Serum Albumin

Nagovitsyn

Chudinova

Лобанов

et al. 2018

Russ. J. Phys. Chem. B

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Structures of nanowires with Zn-ZnO:CuO junctions for detecting ethanol vapors

Peshkova¹,

Dimitrov²,

Nalimova

et al. 2014

Tech. Phys.

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Fractally aggregated micro- and nanosystems synthesized from sols

et al. 2014

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Influence of Binder on Porous Structure of Zeolite Compositions and Their Catalytic Activity

et al. 2020

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Step-by-Step Modeling and Experimental Study on the Sol–Gel Porous Structure of Percolation Nanoclusters

2023

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Non-conventional crystallization techniques have been developed in recent years. Non-conventional crystallization techniques use primary structural elements (for example, clusters) rather than atoms and molecules. Modern nanomaterial science is going through great changes as an entirely new approach of non-conventional growth mechanisms is emerging due to cluster coupling, catalyzing interest in cluster physics. The formation of fractal and percolation clusters has increased. We carried out step-by-step modeling and an experimental study of the formation of fractal and percolation clusters based on tin dioxide and silicon dioxide and formed by sol–gel technology. In this paper, the growth of fractal aggregates (clusters) from sol particles SnO2 and SiO2 based on the modified models of diffusion-limited and cluster–cluster aggregation is discussed. A percolation model using simulated fractal clusters of SnO2 and SiO2 particles is proposed. Experimental data on the sol–gel percolation structure of porous nanocomposites are presented. The modeling of SnO2 and SiO2 particles, which also consist of clusters (the next step in the hierarchy), is shown. We propose a generalized hierarchical three-dimensional percolation cluster model that allows calculating the surface area, knowing the experimental sizes of macropores and taking into account the micro- and mesopores (sizes less than a few nanometers).

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I. E. Kononova

The Study of Aggregation Processes in Colloidal Solutions of Magnetite–Silica Nanoparticles by NMR Relaxometry, AFM, and UV–Vis-Spectroscopy

Microstructure and Magnetic State of Fe₃O₄-SiO₂Colloidal Particles

Fractal-Percolation Structure Architectonics in Sol-Gel Synthesis

Enhancement of Fluorescence of Nanosized ZnO: SiO2 Films in the Presence of Human Serum Albumin

Structures of nanowires with Zn-ZnO:CuO junctions for detecting ethanol vapors

Fractally aggregated micro- and nanosystems synthesized from sols

Influence of Binder on Porous Structure of Zeolite Compositions and Their Catalytic Activity

Step-by-Step Modeling and Experimental Study on the Sol–Gel Porous Structure of Percolation Nanoclusters

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I. E. Kononova

The Study of Aggregation Processes in Colloidal Solutions of Magnetite–Silica Nanoparticles by NMR Relaxometry, AFM, and UV–Vis-Spectroscopy

Microstructure and Magnetic State of Fe3O4-SiO2Colloidal Particles

Fractal-Percolation Structure Architectonics in Sol-Gel Synthesis

Enhancement of Fluorescence of Nanosized ZnO: SiO2 Films in the Presence of Human Serum Albumin

Structures of nanowires with Zn-ZnO:CuO junctions for detecting ethanol vapors

Fractally aggregated micro- and nanosystems synthesized from sols

Influence of Binder on Porous Structure of Zeolite Compositions and Their Catalytic Activity

Step-by-Step Modeling and Experimental Study on the Sol–Gel Porous Structure of Percolation Nanoclusters

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Microstructure and Magnetic State of Fe₃O₄-SiO₂Colloidal Particles