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

Prikhna, T. A.; Gawalek, W.; Savchuk, Yaroslav; Kozyrev, Artem; Wendt, Michael; Melnikov, V. S.; Turkevich, V. Z.; Sergienko, Nina; Moshchil, Viktor; Dellith, Jan; Shmidt, Christa; Дуб, С. Н.; Habisreuther, T.; Litzkendorf, D.; Nagorny, Peter; Sverdun, V. B.; Weber, H.W.; Eisterer, M.; Noudem, Jacques; Dittrich, Ulrich

doi:10.1109/tasc.2009.2018151

Cited by 16 publications

(19 citation statements)

References 12 publications

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“…There were in some cases also relatively large areas of MgO seen in the EBSD mappings with dimensions of several tens of micrometres. As the size of these areas is much too large for being MgO grains (which would have been observed in X‐ray measurements), we ascribe them to surface contamination effects due to the oxygenation, possibly a formation of an Mg‐B‐O phase (Wenzel et al ., ; Prikhna et al ., ). From the map, another interesting result is obtained: within the scanned area of 6 × 6 μm 2 , we obtain a GB length of 417.6 μm, which can provide significant flux pinning at the GBs.…”

Section: Resultsmentioning

confidence: 97%

Analysis of the microstructure of bulk MgB₂ using TEM, EBSD and t‐EBSD

Koblischka-Veneva

Koblischka

Schmauch

et al. 2019

Journal of Microscopy

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Summary EBSD analysis can provide information about grain orientation, texture and grain boundary misorientation of bulk superconducting MgB2 samples intended for supermagnet applications. However, as the grain size of the MgB2 bulks is preferably in the 100–200 nm range, the common EBSD technique operating in reflection mode works only properly on highly dense samples. In order to achieve reasonably good Kikuchi pattern quality on all types of MgB2 samples, we apply here the newly developed transmission EBSD (t‐EBSD) technique to spark‐plasma sintered MgB2 samples. This method requires the preparation of TEM slices by means of focused ion‐beam milling, which are then analysed within the SEM, operating with a custom‐built sample holder. To obtain multiphase scans, we identified the Kikuchi pattern of the MgB4 phase which appears at higher reaction temperatures and may act as additional flux pinning sites. We present here for the first time EBSD mappings of multiple phases, which include MgB2, MgB4 and MgO. Lay Description The electron backscatter diffraction (EBSD) technique operating in the scanning electron microscope provides information on the crystallographic orientation the material by recording Kikuchi patterns. In polycrystalline samples, it becomes possible to analyse the orientations of the grains to each other. The metallic superconductor with the currently highest superconducting transition temperature, MgB2 with a Tc of 38.5 K, can be used in applications in polycrystalline form. One such application of interest are trapped field magnets or supermagnets, where the superconductor cooled in an applied magnetic field can trap the magnetic field as vortices at numerous flux pinning sites in the sample. When the external magnetic field is removed, the sample will stay magnetised as long as it is kept cool, and importantly, the trapped magnetic fields can be much higher as for any permanent magnet. However, the small size of the MgB2 grains in the 100–200 nanometre range requires a different approach when using the EBSD technique on such samples. The recently developed EBSD technique working in transmission mode (t‐EBSD) helps considerably to image such materials. In this approach, a tiny TEM slice has to be milled out from the original sample by using focused ion beam milling. To understand the properties of the flux pinning in the spark‐plasma sintered MgB2 sample, we had to identify the Kikuchi pattern of MgB4, which is another, non‐superconducting phase appearing at higher reaction temperatures required to compact the material. Using this information, we could perform EBSD scans using three different phases, MgB2, MgB4 and MgO. The EBSD mappings enable to see where the secondary phase particles are located in the sample, and to judge if the particles could work as flux pinning sites.

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Section: Resultsmentioning

confidence: 97%

Analysis of the microstructure of bulk MgB₂ using TEM, EBSD and t‐EBSD

Koblischka-Veneva

Koblischka

Schmauch

et al. 2019

Journal of Microscopy

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“…The HP-synthesized samples from mixtures with great quantity of boron (up to Mg:B=1:20) exhibited SC properties [1], Fig. 1h, k and the highest j c as well as T c about 37 K were demonstrated by samples with near MgB 12 composition of matrix (prepared from the Mg:B= 1:8 and 1:20 mixtures).…”

Section: Resultsmentioning

confidence: 92%

“…The most apparent advantages of high-pressure synthesis of MgB 2 are the possibility to suppress the magnesium evaporation and formation of near theoretically dense nanostructural material with good connectivity between grains and high critical current density, j c in a short time (1 hour) [1]. It is considered that due to the comparatively large coherent length pining centers in MgB 2 can be grain boundaries, nanosized grains of secondary phases, and inhomogeneities of the structure.…”

Section: Introductionmentioning

confidence: 99%

Higher borides and oxygen-enriched Mg–B–O inclusions as possible pinning centers in nanostructural magnesium diboride and the influence of additives on their formation

Prikhna

Gawalek

Savchuk

et al. 2010

Physica C: Superconductivity

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The study of high pressure (2 GPa) synthesized MgB 2 -based materials allows us to conclude that higher borides (with near MgB 12 stoichiometry) and oxygen-enriched Mg-B-O inclusions can be pinning centers in nanostructural magnesium diboride matrix (with average grain sizes of 15-37 nm). It has been established that additions of Ti or SiC as well as manufacturing temperature can affect the size, amount and distribution of these inclusions in the material structure and thus, influence critical current density. The superconducting behavior of materials with near MgB 12 stoichiometry of matrix is discussed.

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“…The higher coherent length of MgB 2 (1.6-12 nm [12]) as compared to YBa 2 Cu 3 O 7−δ (or Y123), gives the possibility to attain high critical current densities, j c , and trapped magnetic fields in the polycrystalline MgB 2 -based material, because the grain boundaries are not the obstacles for superconductive current flow as in case of Y123 and can act as pinning centers, so the structure with nanosized grains is preferable for higher j c . Besides, the pinning centers in MgB 2 can be nanosized inclusions of the second phases [13][14][15]. One can increase the critical current density of the material by chemical alloying [16].…”

Section: Nanostructural Superconducting Materials For Fault Currentmentioning

confidence: 99%

Nanostructural Superconducting Materials for Fault Current Limiters and Cryogenic Electrical Machines

et al. 2010

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Materials of the Y-Ba-Cu-O (melt-textured YBa2Cu3O 7−δ -based materials or MT-YBCO) and Mg-B-O (MgB2-based materials) systems with high superconducting performance, which can be attained due to the formation of regularly distributed nanostructural defects and inhomogeneities in their structure can be effectively used in cryogenic technique, in particular in fault current limiters and electrical machines (electromotors, generators, pumps for liquid gases, etc.). The developed processes of high-temperature (900-800• C) oxygenation under elevated pressure (16 MPa) of MT-YBCO and high-pressure (2 GPa) synthesis of MgB2-based materials allowed us to attain high superconductive (critical current densities, upper critical fields, fields of irreversibility, trapped magnetic fields) and mechanical (hardness, fracture toughness, Young modulus) characteristics. It has been shown that the effect of materials properties improvement in the case of MT-YBCO was attained due to the formation of high twin density (20-22 µm −1 ), prevention of macrocracking and reduction (by a factor of 4.5) of microcrack density, and in the case of MgB2-based materials due to the formation of oxygen-enriched as compared to the matrix phase fine-dispersed Mg-B-O inhomogeneities as well as inclusions of higher borides with near-MgB12 stoichiometry in the Mg-B-O matrix (with 15-37 nm average grain sizes). The possibility is shown to obtain the rather high Tc (37 K) and critical current densities in materials with MgB12 matrix (with 95% of shielding fraction as calculated from the resistant curve).

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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

Cited by 16 publications

References 12 publications

Analysis of the microstructure of bulk MgB₂ using TEM, EBSD and t‐EBSD

Analysis of the microstructure of bulk MgB₂ using TEM, EBSD and t‐EBSD

Higher borides and oxygen-enriched Mg–B–O inclusions as possible pinning centers in nanostructural magnesium diboride and the influence of additives on their formation

Nanostructural Superconducting Materials for Fault Current Limiters and Cryogenic Electrical Machines

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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

Cited by 16 publications

References 12 publications

Analysis of the microstructure of bulk MgB2 using TEM, EBSD and t‐EBSD

Analysis of the microstructure of bulk MgB2 using TEM, EBSD and t‐EBSD

Higher borides and oxygen-enriched Mg–B–O inclusions as possible pinning centers in nanostructural magnesium diboride and the influence of additives on their formation

Nanostructural Superconducting Materials for Fault Current Limiters and Cryogenic Electrical Machines

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Analysis of the microstructure of bulk MgB₂ using TEM, EBSD and t‐EBSD

Analysis of the microstructure of bulk MgB₂ using TEM, EBSD and t‐EBSD