Your search keyword '"Alexey I. Salimon"' showing total 4 results

1. Analysis of stress relaxation in bulk and porous ultra-high molecular weight polyethylene (UHMWPE)

Author

Eugene S. Statnik, Alexey I. Salimon, Yulia E. Gorshkova, Natallia S. Kaladzinskaya, Ludmila V. Markova, and Alexander M. Korsunsky

Subjects

UHMWPE, relative density, porosity, stress relaxation, operando analysis, Prony series, X-ray tomography, small angle X-ray scattering (SAXS), Dyben 1.0 miniature 1 kN universal mechanical testing, Polymers and Plastics, General Chemistry

Abstract

The reported study was devoted to the investigation of viscoelastic behavior for solid and porous ultra-high molecular weight polyethylene (UHMWPE) under compression. The obtained experimental stress curves were interpreted using a two-term Prony series to represent the superposition of two coexisting activation processes corresponding to long molecular (~160 s) and short structural (~20 s) time scales, respectively, leading to good statistical correlation with the observations. In the case of porous polymer, the internal strain redistribution during relaxation was quantified using digital image correlation (DIC) analysis. The strongly inhomogeneous deformation of the porous polymer was found not to affect the relaxation times. To illustrate the possibility of generalizing the results to three dimensions, X-ray tomography was used to examine the porous structure relaxation at the macro- and micro-scale levels. DIC analysis revealed positive correlation between the applied force and relative density. The apparent stiffness variation for UHMWPE foams with mixed open and closed cells was described using a newly proposed three-term expression. Furthermore, in situ tensile loading and X-ray scattering study was applied for isotropic solid UHMWPE specimens to investigate the evolution of internal structure and orientation during drawing and stress relaxation in another loading mode.

Published

2023

2. On the grain microstructure–mechanical properties relationships in aluminium alloy parts fabricated by laser powder bed fusion

Author

Yuliya V. Malakhova, Alexey I. Salimon, Pavel A. Somov, Alexander M. Korsunsky, Ryabov D, Eugene S. Statnik, and Kirill V. Nyaza

Subjects

0209 industrial biotechnology, Materials science, Mining engineering. Metallurgy, nanoindentation, Metals and Alloys, TN1-997, EBSD reconstruction, 02 engineering and technology, Nanoindentation, 021001 nanoscience & nanotechnology, Microstructure, 020901 industrial engineering & automation, RS-333 alloy, visual_art, Ultimate tensile strength, Aluminium alloy, visual_art.visual_art_medium, General Materials Science, Composite material, Selective laser melting, 0210 nano-technology, Ductility, Elastic modulus, SLM 3DP, Tensile testing

Abstract

Recent years witnessed progressive broadening of the practical use of 3D-printed aluminium alloy parts, in particular for specific aerospace applications where weight saving is of great importance. Selective laser melting (SLM) is an intrinsically multi-parametric fabrication technology that offers multiple means of controlling mechanical properties (elastic moduli, yield strength, and ductility) through the control over grains size, shape, and orientation. Targeted control over mechanical properties is achieved through the tuning of 3D-printing parameters and may even obviate the need of heat treatment or mechanical post-processing. Systematic studies of grain structure for different printing orientations with the help of EBSD techniques in combination with mechanical testing at different dimensional levels are the necessary first steps to implement this agenda. Samples of 3D-printable Al-Mg-Si RS-333 alloy were fabricated in three orientations with respect to the principal build direction and the fast laser beam scanning direction. Sample structure and proper-ties were investigated using a number of techniques, including EBSD, in situ SEM tensile testing, roughness measurements, and nanoindentation. The as-printed samples were found to display strong variation in Young’s modulus values from nanoindentation (from 43 to 66 GPa) and tensile tests (from 54 to 75 GPa), yield stress and ultimate tensile strength (100–195 and 130–220 MPa) in different printing orientations, and almost constant hardness of about 0.8 GPa. A further preliminary study was conducted to assess the effect of surface finishing on the mechanical performance. Surface polishing was seen to reduce Young’s modulus and yield strength but improves ductility, whereas the influence of sandblasting was found to be more controversial. The experimental results are discussed in connection with the grain morphology and orientation.

Published

2023

3. Effect of graphene oxide and nanosilica modifications on electrospun core-shell PVA–PEG–SiO2@PVA–GO fiber mats

Author

Yuliya Kan, Julia V. Bondareva, Eugene S. Statnik, Julijana Cvjetinovic, Svetlana Lipovskikh, Arkady S. Abdurashitov, Maria A. Kirsanova, Gleb B. Sukhorukhov, Stanislav A. Evlashin, Alexey I. Salimon, and Alexander M. Korsunsky

Subjects

electrospinning, core-shell nanofibers, drug delivery, graphene oxide, fiber modification, silica, General Chemical Engineering, General Materials Science

Abstract

Electrospinning is a well-established method for the fabrication of polymer biomaterials, including those with core-shell nanofibers. The variability of structures presents a great range of opportunities in tissue engineering and drug delivery by incorporating biologically active molecules such as drugs, proteins, and growth factors and subsequent control of their release into the target microenvironment to achieve therapeutic effect. The object of study is non-woven core-shell PVA–PEG–SiO2@PVA–GO fiber mats assembled by the technology of coaxial electrospinning. The task of the core-shell fiber development was set to regulate the degradation process under external factors. The dual structure was modified with silica nanoparticles and graphene oxide to ensure the fiber integrity and stability. The influence of the nano additives and crosslinking conditions for the composite was investigated as a function of fiber diameter, hydrolysis, and mechanical properties. Tensile mechanical tests and water degradation tests were used to reveal the fracture and dissolution behavior of the fiber mats and bundles. The obtained fibers were visualized by confocal fluorescence microscopy to confirm the continuous core-shell structure and encapsulation feasibility for biologically active components, selectively in the fiber core and shell. The results provide a firm basis to draw the conclusion that electrospun core-shell fiber mats have tremendous potential for biomedical applications as drug carriers, photocatalysts, and wound dressings.

Published

2022

4. In Situ Formation of Nanoporous Silicon on a Silicon Wafer via the Magnesiothermic Reduction Reaction (MRR) of Diatomaceous Earth

Author

Svetlana A. Lipovskikh, Yuliya Kan, Patrick Aggrey, Denis M. Zhigunov, Igor A. Salimon, Alexander M. Korsunsky, Sergey Yu. Luchkin, Bakhodur Abdusatorov, and Alexey I. Salimon

Subjects

Materials science, Silicon, General Chemical Engineering, chemistry.chemical_element, Substrate (electronics), Focused ion beam, Article, lcsh:Chemistry, chemistry.chemical_compound, symbols.namesake, in situ processing, General Materials Science, Wafer, Crystalline silicon, nanoflakes, Black silicon, black silicon, fractal structure, diatomaceous earth, magnesiothermic reduction reaction, lcsh:QD1-999, chemistry, Chemical engineering, light absorption, symbols, Raman spectroscopy, Layer (electronics), surface reflection

Abstract

Successful direct route production of silicon nanostructures from diatomaceous earth (DE) on a single crystalline silicon wafer via the magnesiothermic reduction reaction is reported. The formed porous coating of 6 &micro, m overall thickness contains silicon as the majority phase along with minor traces of Mg, as evident from SEM-EDS and the Focused Ion Beam (FIB) analysis. Raman peaks of silicon at 519 cm&minus, 1 and 925 cm&minus, 1 were found in both the film and wafer substrate, and significant intensity variation was observed, consistent with the SEM observation of the directly formed silicon nanoflake layer. Microstructural analysis of the flakes reveals the presence of pores and cavities partially retained from the precursor diatomite powder. A considerable reduction in surface reflectivity was observed for the silicon nanoflakes, from 45% for silicon wafer to below 15%. The results open possibilities for producing nanostructured silicon with a vast range of functionalities.

Published

2020