Yaroslav Savchuk scite author profile

Yaroslav Savchuk

4Publications

46Citation Statements Received

16Citation Statements Given

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Affiliations

National Academy of Sciences of Ukraine, V. Bakul Institute for Superhard Materials

Publications

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Formation of Higher Borides During High-Pressure Synthesis and Sintering of Magnesium Diboride and Their Positive Effect on Pinning and Critical Current Density

Prikhna

Gawalek

Savchuk

et al. 2009

IEEE Trans. Appl. Supercond.

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Critical current density ( c ) of high-pressure (2 GPa) manufactured MgB 2 -based superconductors depends on the amount and distribution of higher borides (MgB 12 ) in MgB 2 matrix, which in turn are determined by the nature of the initial components first of all B or MgB 2 and the temperature of sintering or synthesis. Ti and Ta additions can improve c by promoting the higher boride formation via impurity hydrogen absorption, thus preventing MgH 2 detrimental for c being formed, which possibly increases the MgB 12 nucleation barrier. SiC (0.2-0.8 m) addition increases c of MgB 2 , allowing us to get c = 10 6 A cm 2 at 20 K in the 1 T field: pinning is increased by SiC and higher boride grains and there is no notable interaction between SiC and MgB 2 . As the synthesis temperature increases from 800 to 1050 C, Ti and SiC additions may affect the oxygen segregation and formation of Mg-B-O inclusions enriched with oxygen as compared to the amount of oxygen in the MgB 2 matrix, which can also promote an increase in pinning. Materials high-pressure synthesized from Mg and B taken in 1:4, 1:6, 1:7, 1:8, 1:10, 1:12, 1:20 ratios were superconductive with T c of about 37 K. High c (7 10 4 2 10 4 A cm 2 in zero field at 10-30 K, respectively) showed materials with the matrix composition near MgB 12 stoichiometry, they have doubled microhardness of MgB 2 .

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Flux mapping at 77K and local measurement at lower temperature of thin-wall YBaCuO single-domain samples oxygenated under high pressure

Chaud

Noudem

Prikhna³

et al. 2009

Physica C: Superconductivity

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High-pressure oxygenation of thin-wall YBCO single-domain samples

Chaud

Savchuk

Sergienko

et al. 2008

J. Phys.: Conf. Ser.

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Spark Plasma Synthesis and Sintering of Superconducting MgB<sub>2</sub>-Based Materials

Prikhna

Noudem

Gawalek³

et al. 2012

MSF

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Superconducting (SC) and mechanical properties of spark plasma (or SPS) produced MgB2 –based materials allow their efficient applications in fault current limiters, superconducting electromotors, pumps, generators, magnetic bearings, etc. The synthesized from Mg and B at 50 MPa, 1050 °C for 30 min material has a density of 2.52 g/cm3, critical current density, jc = 7.1•105 A/cm2 at 10 K , 5.4 •105 A/cm2 at 20 K, and 9•104 A/cm2 at 35 K in zero magnetic field; at 20 K its field of irreversibility Birr(20)=7 T and upper critical field Bc2(20)=11 T; microhardness HV=10.5 GPa and fracture toughness K1C =1.7 MPa•m1/2 at 4.9 N-load. SPS-manufactured in- situ MgB2-based materials usually have somewhat higher jc than sintered ex-situ. The pressure variations from 16 to 96 MPa during the SPS-process did not affect material SC characteristics significantly; the jc at 10-20 K was slightly higher and the material density was higher by 11%, when pressures of 50-96 MPa were used. The structure of SPS-produced MgB2 material contains Mg-B-O inclusions and inclusions of higher borides (of compositions near MgB4, MgB7, MgB12, MgB17, MgB20), which can be pinning centers. The presence of higher borides in the MgB2 structure can be revealed by the SEM and Raman spectroscopy.

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