Your search keyword '"Taskaev SV"' showing total 8 results

1. Preparation, phase stability, and magnetization behavior of high entropy hexaferrites.

Author

Zhivulin VE, Trofimov EA, Zaitseva OV, Sherstyuk DP, Cherkasova NA, Taskaev SV, Vinnik DA, Alekhina YA, Perov NS, Naidu KCB, Elsaeedy HI, Khandaker MU, Tishkevich DI, Zubar TI, Trukhanov AV, and Trukhanov SV

Abstract

The polycrystalline SrFe 12 O 19 samples deeply substituted up to at.67% by Al 3+ , Ga 3+ , In 3+ , Co 3+ , and Cr 3+ cations with a high configurational mixing entropy were prepared by solid-phase synthesis. Phase purity and unit cell parameters were obtained from XRD and analyzed versus the average ionic radius of the iron sublattice. The crystallite size varied around ∼4.5 μm. A comprehensive study of the magnetization was realized in various fields and temperatures. The saturation magnetization was calculated using the Law of Approach to Saturation. The accompanying magnetic parameters were determined. The magnetic crystallographic anisotropy coefficient and the anisotropy field were calculated. All investigated magnetization curves turned out to be nonmonotonic. The magnetic ordering and freezing temperatures were extracted from the ZFC and FC curves. The average size of magnetic clusters varied around ∼350 nm. The high values of the configurational mixing entropy and the phenomenon of magnetic dilution were taken into account., Competing Interests: The authors declare no competing interests., (© 2023 The Author(s).)

Published

2023

2. Reprogrammable Soft Swimmers for Minimally Invasive Thrombus Extraction.

Author

Pozhitkova AV, Kladko DV, Vinnik DA, Taskaev SV, and Vinogradov VV

Abstract

Thrombosis-related diseases are the primary cause of death in the world. Despite recent advances in thrombosis treatment methods, their invasive nature remains a crucial factor, which leads to considerable deadly consequences. Soft magnetic robots are attracting widespread interest due to their fast response, remote actuation, and shape reprogrammability and can potentially avoid the side effects of conventional approaches. This paper outlines a new approach to the thrombosis treatment via reprogrammable magnetic soft robots that penetrate, hook, and extract the plasma clots in a vein-mimicking system under applied rotating magnetic fields. We present shape-switching bioinspired soft swimmers, capable of locomotion by different mechanisms in vein-mimicking flow conditions and whose swimming efficiency is similar to animals. Further, we demonstrate the potential of a developed robot for minimally invasive thromboextraction with and without fibrinolytic usage, including hooking the plasma clot for 3.1 ± 1.1 min and extracting it from the vein-mimicking system under the applied magnetic fields. We consider an interesting solution for thrombosis treatment to avoid substantial drawbacks of the existing methods.

Published

2022

3. Creation and Magnetic Study of Ferrites with Magnetoplumbite Structure Multisubstituted by Al 3+ , Cr 3+ , Ga 3+ , and In 3+ Cations.

Author

Zhivulin VE, Sherstyuk DP, Zaitseva OV, Cherkasova NA, Vinnik DA, Taskaev SV, Trofimov EA, Trukhanov SV, Latushka SI, Tishkevich DI, Zubar TI, and Trukhanov AV

Abstract

Multisubstituted barium ferrites with a magnetoplumbite structure were obtained by the method of solid-phase reactions with ferritization and pre-firing. Three-charged, mainly diamagnetic cations Al 3+ , Cr 3+ , Ga 3+ , and In 3+ were chosen as substituents for the Fe 3+ iron cations, the proportion of which in solid solutions did not exceed 50%. The values of the configurational mixing entropy were calculated for all the compositions. A slight deviation of the chemical composition of the obtained solid solutions from the nominal value was established by the energy-dispersive X-ray spectroscopy method. The phase purity and values of the unit cell parameters were refined from X-ray scattering data using full-profile analysis in the Rietveld method. A non-monotonic behavior of the unit cell parameters as a function of the B-sub-lattice average ionic radius of the magnetoplumbite structure was found. A minimum unit cell volume of ~667.15 Å 3 was found for the composition BaFe 6.11 Al 1.56 Cr 2.17 Ga 2.16 O 19 with a B-sub-lattice average ionic radius of ~7.449 Å. The average crystallite size varied within 5.5-6.5 μm. The temperature and field dependencies of the magnetization have been measured. The values of the saturation magnetization, residual magnetization, hysteresis loop squareness, and coercivity at 50 K and 300 K were extracted from the experimental data. Using the Law of Approach to Saturation, the magnetic crystallographic anisotropy coefficient and anisotropy field were calculated. Multisubstitution leads to a significant decrease in such magnetic parameters as the magnetic ordering temperature and spontaneous magnetization at both temperatures. The maximum magnetic ordering temperature of ~297.7 K was found for the composition BaFe 5.84 Ga 6.19 O 19 with a B-sub-lattice average ionic radius of ~7.586 Å in a field of 500 Oe. A maximum saturation magnetization of ~24.7 emu/g was found for the composition BaFe 5.84 Ga 6.19 O 19 with a B-sub-lattice average ionic radius of ~7.586 Å at 50 K. A maximum hysteresis loop squareness of ~0.72 was found for the composition BaFe 6.11 Al 1.56 Cr 2.17 Ga 2.16 O 19 with an average ionic radius of ~7.449 Å at 50 K. A maximum magnetic crystallographic anisotropy coefficient of ~2.09 × 10 5 Erg/g was found for the composition BaFe 6.19 Al 1.25 Cr 1.57 Ga 1.74 In 1.26 O 19 with a B-sub-lattice average ionic radius of ~7.706 Å at 50 K. The frustrated magnetic state including the nano-sized clusters with an average diameter in the range of 50-200 nm was established from the results of measuring the ZFC and FC temperature magnetizations. The interpretation of the obtained experimental data is carried out taking into account the increased stability of high-entropy phases and regular changes in the intensity of the Fe 3+ (Al 3+ , Cr 3+ , Ga 3+ , In 3+ )-O 2- -Fe 3+ (Al 3+ , Cr 3+ , Ga 3+ , In 3+ ) indirect superexchange interactions as a result of magnetic dilution of the iron sub-lattice in the magnetoplumbite structure.

Published

2022

4. A-Site Cation Size Effect on Structure and Magnetic Properties of Sm(Eu,Gd)Cr 0.2 Mn 0.2 Fe 0.2 Co 0.2 Ni 0.2 O 3 High-Entropy Solid Solutions.

Author

Vinnik DA, Zhivulin VE, Trofimov EA, Gudkova SA, Punda AY, Valiulina AN, Gavrilyak M, Zaitseva OV, Taskaev SV, Khandaker MU, Alqahtani A, Bradley DA, Sayyed MI, Turchenko VA, Trukhanov AV, and Trukhanov SV

Abstract

Three high-entropy Sm(Eu,Gd)Cr 0.2 Mn 0.2 Fe 0.2 Co 0.2 Ni 0.2 O 3 perovskite solid solutions were synthesized using the usual ceramic technology. The XRD investigation at room temperature established a single-phase perovskite product. The Rietveld refinement with the FullProf computer program in the frame of the orthorhombic Pnma (No 62) space group was realized. Along with a decrease in the V unit cell volume from ~224.33 Å 3 for the Sm-based sample down to ~221.52 Å 3 for the Gd-based sample, an opposite tendency was observed for the unit cell parameters as the ordinal number of the rare-earth cation increased. The average grain size was in the range of 5-8 μm. Field magnetization was measured up to 30 kOe at 50 K and 300 K. The law of approach to saturation was used to determine the M s spontaneous magnetization that nonlinearly increased from ~1.89 emu/g (Sm) up to ~17.49 emu/g (Gd) and from ~0.59 emu/g (Sm) up to ~3.16 emu/g (Gd) at 50 K and 300 K, respectively. The M r residual magnetization and H c coercive force were also determined, while the SQR loop squareness, k magnetic crystallographic anisotropy coefficient, and H a anisotropy field were calculated. Temperature magnetization was measured in a field of 30 kOe. ZFC and FC magnetization curves were fixed in a field of 100 Oe. It was discovered that the T mo magnetic ordering temperature downward-curve decreased from ~137.98 K (Sm) down to ~133.99 K (Gd). The spin glass state with ferromagnetic nanoinclusions for all the samples was observed. The average and D max maximum diameter of ferromagnetic nanoinclusions were calculated and they were in the range of 40-50 nm and 160-180 nm, respectively. The mechanism of magnetic state formation is discussed in terms of the effects of the A-site cation size and B-site poly-substitution on the indirect superexchange interactions.

Published

2021

5. Shape anisotropic magnetic thrombolytic actuators: synthesis and systematic behavior study.

Author

Zakharzhevskii MA, Anastasova EI, Kladko DV, Prilepskii AY, Gorshkova MN, Vinnik DA, Taskaev SV, and Vinogradov VV

Abstract

Thrombosis-related diseases are undoubtedly the deadliest disorders. During the last decades, numerous attempts were made to reduce the overall death rate and severe complications caused by treatment delays. Significant progress has been made in the development of nanostructured thrombolytics, especially magnetically controlled. The emergence of thrombolytic magnetic actuators, which can deliver tPA to the occlusion zone and perform mechanical disruption of the fibrin network under the application of a rotating magnetic field (RMF), can be considered for the next generation of thrombolytic drugs. Thus, we propose a systematic study of magnetic-field mediated mechanically-assisted thrombolysis (MFMMAT) for the first time. Four types of magnetic particles with different morphology and dimensionality were utilized to assess their impact on model clot lysis under different RMF parameters. Chain-like 1D and sea urchins-like 3D structures were found to be the most effective, increasing thrombolysis efficacy to nearly 200%. The drastic difference was also observed during the dissolution of 3 days old blood clots. Pure plasminogen activator had almost no effect on clot structure during 30 minutes of treatment while applying MFMMAT led to the significant decrease of clot area, thus uncovering the possibility of deep venous thrombosis therapy.

Published

2021

6. Polysubstituted High-Entropy [LaNd](Cr 0.2 Mn 0.2 Fe 0.2 Co 0.2 Ni 0.2 )O 3 Perovskites: Correlation of the Electrical and Magnetic Properties.

Author

Zhivulin VE, Trofimov EA, Gudkova SA, Pashkeev IY, Punda AY, Gavrilyak M, Zaitseva OV, Taskaev SV, Podgornov FV, Darwish MA, Almessiere MA, Slimani Y, Baykal A, Trukhanov SV, Trukhanov AV, and Vinnik DA

Abstract

La-, Nd- and La/Nd-based polysubstituted high-entropy oxides (HEOs) were produced by solid-state reactions. Composition of the B-site was fixed for all samples (Cr 0.2 Mn 0.2 Fe 0.2 Co 0.2 Ni 0.2 ) with varying of A-site cation (La, Nd and La 0.5 Nd 0.5 ). Nominal chemical composition of the HEOs correlates well with initial calculated stoichiometry. All produced samples are single phase with perovskite-like structure. Average particle size is critically dependent on chemical composition. Minimal average particle size (~400 nm) was observed for the La-based sample and maximal average particle size (5.8 μm) was observed for the Nd-based sample. The values of the configurational entropy of mixing for each sample were calculated. Electrical properties were investigated in the wide range of temperatures (150-450 K) and frequencies (10 -1 -10 7 Hz). Results are discussed in terms of the variable range hopping and the small polaron hopping mechanisms. Magnetic properties were analyzed from the temperature and field dependences of the specific magnetization. The frustrated state of the spin subsystem was observed, and it can be a result of the increasing entropy state. From the Zero-Field-Cooling and Field-Cooling regimes (ZFC-FC) curves, we determine the average and S max maximum size of a ferromagnetic nanocluster in a paramagnetic matrix. The average size of a ferromagnetic cluster is ~100 nm (La-CMFCNO) and ~60 nm (LN-CMFCNO). The S max maximum size is ~210 nm (La-CMFCNO) and ~205 nm (LN-CMFCNO). For Nd-CMFCNO, spin glass state (ferromagnetic cluster lower than 30 nm) was observed due to f-d exchange at low temperatures.

Published

2021

7. Extremely Polysubstituted Magnetic Material Based on Magnetoplumbite with a Hexagonal Structure: Synthesis, Structure, Properties, Prospects.

Author

Vinnik DA, Zhivulin VE, Trofimov EA, Starikov AY, Zherebtsov DA, Zaitseva OV, Gudkova SA, Taskaev SV, Klygach DS, Vakhitov MG, Sander EE, Sherstyuk DP, and Trukhanov AV

Abstract

Crystalline high-entropy single-phase products with a magnetoplumbite structure with grains in the μm range were obtained using solid-state sintering. The synthesis temperature was up to 1400 °C. The morphology, chemical composition, crystal structure, magnetic, and electrodynamic properties were studied and compared with pure barium hexaferrite BaFe 12 O 19 matrix. The polysubstituted high-entropy single-phase product contains five doping elements at a high concentration level. According to the EDX data, the new compound has a formula of Ba(Fe₆Ga 1.25 In 1.17 Ti 1.21 Cr 1.22 Co 1.15 )O 19 . The calculated cell parameter values were a = 5.9253(5) Å, c = 23.5257(22) Å, and V = 715.32(9) ų. The increase in the unit cell for the substituted sample was expected due to the different ionic radius of Ti/In/Ga/Cr/Co compared with Fe 3+ . The electrodynamic measurements were performed. The dielectric and magnetic permeabilities were stable in the frequency range from 2 to 12 GHz. In this frequency range, the dielectric and magnetic losses were -0.2/0.2. Due to these electrodynamic parameters, this material can be used in the design of microwave strip devices.

Published

2019

8. Novel electrical transport properties of native Fe-Nb oxide layers leading to unilateral conductivity of a refractory metallic glass.

Author

Trifonov AS, Lubenchenko AV, Ketov SV, Taskaev SV, and Louzguine-Luzgin DV

Abstract

Fe-based metallic glasses (also called amorphous alloys) are known to have high hardness and high wear resistance. Here we study and present a Fe-Nb amorphous material with an unusual type of electrical conductivity behavior. The electrical transport properties of Fe-Nb oxide layers were studied by measuring local current-voltage characteristics by the atomic-force microscopy technique. At certain voltage levels the samples containing native oxides showed clearly asymmetrical conductivity relative to polarity of the applied potential. Fe-Nb metallic glassy surface oxide film growth process was monitored at ambient conditions. The growth rate keeps constant during the initial 2.5 hours. After that the growth rate drastically decreases and becomes almost zero while the final oxide thickness is 1.0-1.5 nm. The Fe-Nb film sample annealed for 15 minutes at 300 °C demonstrates several times larger oxide thickness and becomes an insulator. X-ray photoelectron spectroscopy was used to characterize the oxidation states in the surface amorphous oxides. This material can be readily applied as inexpensive nanoscale tunnel diode operating at the commonly utilized voltage of ±5 V.

Published

2019