ORALS

SESSION: AdvancedMaterialsMonAM-R10	6th Intl. Symp. on New & Advanced Materials & Technologies for Energy, Environment, Health & Sustainable Development
Mon. 28 Nov. 2022 / Room: Saitong
Session Chairs: Fernand Marquis; Session Monitor: TBA

11:55: [AdvancedMaterialsMonAM02] OS Plenary
STRUCTURE, PROPERTIES AND APPLICATION of MT-YBCO and bulk MgB2-BASED SUPERCONDUCTORS
Tetiana Prikhna¹ ; Michael Eisterer² ; Vladimir Sokolovskiy³ ; Viktor Moshchil⁴ ; Bernd Büchner⁵ ; Xavier Chaud⁶ ; Dmitriy Efremov⁵ ; Dirk Lindackers⁵ ; Fernand Marquis⁷ ; Semyon Ponomarov⁸ ; Vladimir Sverdun⁹ ; ¹V. Bakul Institute NASU, Kiev, Ukraine; ²Institute of Atomic and Subatomic Physics, TU Wien, Vienna, Austria, Vienna, Austria; ³Ben-Gurion University of the Negev, Beer-Sheva, Israel, Beer-Sheva 84105, Israel; ⁴Institute for Superhard Materials, Kiev, Ukraine; ⁵Leibniz-Institut für Festkörper- und Werkstoffforschung Dresden e. V., Dresden, Germany; ⁶Laboratoire National des Champs Magnétiques Intenses (LNCMI/CNRS), Grenoble, France; ⁷San Diego State University, San Diego, United States; ⁸Institute of Semiconductor Physics, Kiev, Ukraine; ⁹Institute for Superhard Materials of the National Academy of Sciences of Ukraine, Kiev, Ukraine;
Paper Id: 448 [Abstract]

A comprehensive investigation of the structural, superconducting and mechanical characteristics of MgB2-based bulk materials and melt-textured (MT) -YBCO, prepared under different pressure-temperature-time conditions, establishes correlations responsible for attaining high functional properties of the superconducting materials and fields of their effective application. The analysis of MgB2 and MT-YBCO from the point of view of their application in inductive fault current limiters and electrical machines showed the competientability of both MgB2 and MT-YBCO materials. The advantages and disadvantages of the both materials are discussed. A successful development of hydrogen as an energy carrier involves the transportation of liquid hydrogen over long distances. This would provide a widely available coolant for superconducting materials that operate efficiently at 20 K. Very promissing are MT-YBCO and MgB2-based materials. MT-YBCO can create higher magnetic fields but its preparation takes much longer and is rather complicated and expensive. Microcraking during oxygenation of the Y123 structure may lead to the appearance of hot sports during the operation of electrical devices. Oxygenation under high oxygen pressure and high temperature reduces the process duration and cracking hence leading to an increase of the critical current density and a reduction of the material anysotropy. The mechanical characteristics increase as well. The drawback of MgB2 ceramics can be its high sensitivity toward flux jumps, particularly reducing shield of AC magnetic fields. Manufacturing under high pressure results in dense MgB2 ceramics with a high mechanical perfomance. Both materials are promising for practical applications but futher reseach activity shoud be performed to undestand the mechanisms of their unique properties.

SESSION: AdvancedMaterialsMonPM1-R10	6th Intl. Symp. on New & Advanced Materials & Technologies for Energy, Environment, Health & Sustainable Development
Mon. 28 Nov. 2022 / Room: Saitong
Session Chairs: Tetiana Prikhna; Session Monitor: TBA

15:15: [AdvancedMaterialsMonPM108] OS
MAGNETIC PROPERTIES AND APPLICATIONS OF IRON OXIDES NANOPOWDERS OBTAINED BY THE ELECTRO-EROSION DISPERSION AND SINTERED FROM THEM BULKS AT HIGH-PRESSURE
Tetiana Prikhna¹ ; Mykola Monastyrov² ; Bernd Büchner³ ; Fernand D. S. Marquis⁴ ; Florian Kongoli⁵ ; Sebastian Gaß³ ; Aniruddha Sathyadharma Prasad³ ; Ivan Soldatov³ ; Pavel Potapov³ ; Kai Neufeld³ ; Vitaliy Romaka³ ; Lars Giebeler³ ; Valeriy Shatilo⁶ ; Myroslav Karpets⁷ ; Anja Wolter Giraud³ ; Alexander Borimskiy⁸ ; ¹V. Bakul Institute NASU, Kiev, Ukraine; ²Open International University of Human Development Ukraine, Kiev, Ukraine; ³Leibniz-Institut für Festkörper- und Werkstoffforschung Dresden e. V., Dresden, Germany; ⁴United Nano technologies (UNT) and Integrated Materials Technologies and Systems (IMTS), Rapid City, United States; ⁵FLOGEN Technologies, Mont-Royal, Canada; ⁶D.F. Chebotaryov Institute of Gerontology of the National Academy of Medical Sciences of Ukraine, Kyiv, Ukraine; ⁷Institute for Superhard Materials, Kiev, Ukraine; ⁸V. Bakul Institute for Superhard Materials of the National Academy of Sciences of Ukraine, Kyiv, Ukraine;
Paper Id: 394 [Abstract]

Nanodispersed iron oxides obtained by us using the electroerosion dispersion (EED) technology [1, 2] have a wide range of applications. The EED method can be used for recycling of metals chips and granules. The polyvalent nanopowders of iron oxides due to magnetic characteristics, in particular, are successfully used in medicine for blood thinning and as antianemic specimen of prolonged action to saturate the blood with oxygen and maintain saturation at the optimal level for human life; in animal husbandry as feed additives to accelerate the growth of livestock and in increasing the laying capacity of birds. In 2020-2021 the dietary supplement "Lisoferrin" and feed additive "Nano-Fe" were developed and certified in Ukraine, although the mechanism of their action the appertaining processes remain not fully understood. It has been observed that the developed nanopowders of iron oxides also have a positive effect on the treatment of a wide range of other diseases, such as: related to dementia, cognitive disorders, contribute to the reduction of blood sugar levels, accelerate the healing of purulent wounds in varicose veins and the fusion of broken bones, etc. In addition, the developed nanopowders are characterized by a high ability to absorb ultra-high-frequency radiation (higher than the commercial powders of iron oxide ‟Magsilica”, produced in Germany) [1], and are therefore promising for the production of shielding which absorb ultrahigh frequency electromagnetic radiation. The iron oxide nanopowders developed in this research have a high adsorption capacity in relation to heavy metal ions [3] and are promising for water purification and wastewater treatment [3, 4]. From the point of view of magnetic properties, they are close to soft magnetic materials and demonstrate superparamagnetic behavior [1]. The bulk materials consolidated from the Fe-O nano powders under high pressure conditions (using 2 GPa pressure at 1200 and 1300 °C for 0.07 h in contact with hexagonal boron nitride) also exhibited soft magnetic behavior, which makes their use very promising in electrical engineering and in other branches of industrial technology. The structure of sintered materials was investigated by X-ray diffraction with Rietveld refinement and showed that the materials consolidated under 2 GPa at 900 and 1000 °C contained 75–80 wt.% FeO and 25–20 wt.% Fe, and the materials sintered at 1100 ^oC, in parallel with 32 wt. % FeO and 2 wt.% Fe was present contained a significant amount of Fe₃N: 66 wt.%. However, the structure of the same materials consolidated at 1200-1300 °C contained about 100% of the Fe₃N phase. Thus, under conditions of high pressures and temperatures with increasing sintering temperature, reduction of iron oxide was observed, followed by its nitriding with nitrogen released from the boron nitride, which led to improvement of soft magnetic characteristics of sintered materials.

References:
[1] B. Halbedel, T. Prikhna, P. Quiroz, T. Kups, M. Monastyrov, Current Applied Physics, 18(11) (2018) 1410–1414.
[2] M.K. Monastyrov, T.A. Prikhna, A.G. Mamalis, W. Gawalek, P.M. Talanchuk, R.V. Shekera Nanotechnology Perceptions, 4 (2008) 179–187.
[3] M. Monastyrov, T. Prikhna, B. Halbedel, A.G. Mamalis, O. Prysiazhna, Nanotechnology Perceptions. 15(1) (2019) 48–57. N24MO18A
[4] G. Kochetov, T. Prikhna, D. Samchenko, O. Prysiazhna, M. Monastyrov, V. Moshchil, A. Mamalis, Nanotechnology Perceptions, 17(1) (2021) 9–12.