Enhancement of the critical current density in MgB<sub>2</sub>wires doped with Ni nanoparticles

Novosel, Nikolina; Galić, Stipe; Pajić, Damir; Skoko, Željko; Lončarek, Ivana; Mustapić, Mislav; Zadro, Krešo; Babić, Emil

doi:10.1088/0953-2048/25/9/095018

Cited by 19 publications

(24 citation statements)

References 41 publications

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“…Researchers adopted either in-situ route using Mg/B powder mixtures with phase formation during a heat treatment or exsitu route using pre reacted MgB 2 powder as precursor and found that the properties of bulk MgB 2 samples are crucially affected by the preparation technique. Significant improvement in critical current carrying capacities of in-situ MgB 2 by various additives and nanoparticles [5][6][7][8][9][10][11][12][13][14] was observed, as the substitution reaction can easily occur via this route. For the application purpose, due to fewer fabrication parameters, ex situ method is more attractive and has been utilized by many researchers for making wires 15,16 and tapes.…”

Section: Introductionmentioning

confidence: 98%

Effect of excess Mg and nano-additives on the superconducting properties of weakly connected bulk MgB2

Bhadauria

Gupta

Kishan

et al. 2013

Journal of Applied Physics

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Articles you may be interested inConnectivity and critical current density of in-situ processed MgB2 superconductors: Effect of excess Mg and non-carbon based additives A new scaling relation for n-AlN doped superconducting MgB2SiC and carbon nanotube distinctive effects on the superconducting properties of bulk Mg B 2Series of ex-situ polycrystalline MgB 2 bulk samples, by adding different additives like more of excess Mg (5 wt. %), nanoparticles of Ag (3 wt. %), and SiC (10 wt. %) to a previously optimized composition MgB 2 þ Mg (5 wt. %), were prepared by solid state synthesis route. Detailed investigations were carried out by XRD, SEM, and thermoelectric power S(T), resistivity q(T), and magnetization M(B) at temperatures T ¼ 4.2-300 K and applied fields B ¼ 0-8 T. All the samples typically show low connectivity (i.e., normal state current carrying cross section $0.9%-3%). The effect of different additives was different on the critical current density (J c ) of the samples. The J c , for instance at T ¼ 4.2 K and B ¼ 1 T, varied between 4.8 Â 10 7 and 2.8 Â 10 8 A/m 2 for various samples. In comparison to the previously optimized values, the J c was enhanced by further addition of 5 wt. % Mg and degraded both by nano-SiC and nano-Ag addition. However, many of the other properties of the samples were not much affected. For instance, the samples did not show any change in the superconducting onsets, S(T) and the parallel upper critical field (B jj c2 (T) $ 11-13 T at 20 K and 20-21 T at 4.2 K). The J c (B) dependence also shows similar behavior in all the samples, where the J c is found to scale as B À1 up to a sample independent crossover field B cr $ 2 T and 1.3 T at T ¼ 4.2 and 20 K, respectively. At higher fields B > B cr , the J c (B) curves branch out and decrease rapidly towards zero at a sample dependent characteristic field. We try to understand these results quantitatively in terms of changes in connectivity, pinning, and anisotropy driven percolation. However, all our results and analysis point out that the intra-particle regions stay unaffected and mainly the inter-particle regions get affected by the additives leading to the J c variation in the weakly connected samples.

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Section: Introductionmentioning

confidence: 98%

Effect of excess Mg and nano-additives on the superconducting properties of weakly connected bulk MgB2

Bhadauria

Gupta

Kishan

et al. 2013

Journal of Applied Physics

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“…The possibility of long-range pinning by magnetic nanoparticles prompted research aimed at finding the most suitable nanoparticles for introduction of magnetic pinning into MgB 2 [13][14][15][16][17][18][19]. The idea of magnetic-type pinning in MgB 2 is still controversial.…”

Section: Introductionmentioning

confidence: 99%

Enhancing superconducting properties of MgB₂pellets by addition of amorphous magnetic Ni–Co–B nanoparticles

Mustapić

Horvat

Hossain

et al. 2013

Supercond. Sci. Technol.

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Amorphous magnetic Ni-Co-B nanoparticles with an average size of 5 nm were added to precursor powders of MgB2 superconductor. The preparation procedure for MgB2 pellets was optimized for obtaining the best critical current density ( Jc) at elevated magnetic fields. Addition of Ni-Co-B decreases the Jc for heat treatment of precursor powders at 650 ° C. Heat treatments at 770 ° C and higher improve Jc at 20 and 5 K. This improvement occurs at both temperatures through the increase of the effective connectivity between MgB2 crystals. Vortex pinning was enhanced at 5 K, but not at 20 K. Ni-Co-B nanoparticles reacted with Mg in heat treatments above 730 ° C, forming Mg2Ni and MgCo2 nanoparticles. Ni-Co-B addition was associated with lower oxygen content in MgB2, indicating that reduction of MgO content is the mechanism for improvement of grain connectivity. Decomposition of magnetic Ni-Co-B nanoparticles results mostly in nonmagnetic nanoparticles, so magnetic pinning did not occur in our samples.

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“…This is explained with limited growth of MgB2 grains, due to the formation of earlier mentioned nanoprecipitates at grain boundaries. Furthermore, the mean size of hexagonal shapes for both MgB2 samples (Samples 1 and 2), which should correspond to MgB2 grains according to study from our previous works, [16,17] was determined from FE-SEM micrographs, as shown in Figures 3 (a) and 4 (a), respectively. The size distributions of corresponding measured diameters of hexagonal grains are shown in Figures 5 and 6.…”

Section: Xrd and Fe-semmentioning

confidence: 97%

“…The study of the influence of the magnetic nanoparticles addition on electromagnetic properties of MgB2 is given elsewhere. [15][16][17][18] The MgB2 sample, formed after the addition of NiCoB nanoparticles (2.67 w. %) to Mg and B precursor powders and sintering at 650 C, which represent the subject of this research, was chosen due to the observed improvement of critical current density in respect to the MgB2 sample without the addition of the nanoparticles. [15] Generally, the identification of all phases present in the resulting MgB2 samples formed after the addition of the nanoparticles with various chemical composition to MgB2 precursor powders (sintered at various temperatures), along with the determination of their morphologies and dimensions, is crucial in understanding and interpreting the observed changes in the superconducting properties of MgB2 (either positive or negative ones).…”

Section: Introductionmentioning

confidence: 99%

Microstructural Features of Magnetic NiCoB Nanoparticles Addition to MgB2 Precursor Powders

Lončarek¹,

Tonejc²,

Skoko³

et al. 2017

Croat. Chem. Acta

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Magnesium diboride (MgB2) is a superconductor characterized by interesting properties like rather high superconducting transition temperature Tc = 39 K, long coherence length and low anisotropy. In addition, it has a very simple crystal structure and low density. Those properties make the MgB2 an ideal candidate for a wide range of applications.To improve the electromagnetic properties of MgB2, magnetic nickel-cobalt-boron (NiCoB) nanoparticles (mean grain size 17 ± 3 nm) were added to Mg and B precursor powders and sintered at 650 C, i.e. the temperature of MgB2 superconductor formation. The nearly spherical NiCoB nanoparticles, as-prepared by the chemical reduction of metallic salts, were amorphous according to previous study. The resulting MgB2 sample, formed after the sintering at 650 C, was subjected to detailed microstructural analysis which included the application of various experimental methods: XRD, FE-SEM, EDS, elemental mapping, TEM and SAED. The methods confirmed the formation of new crystal CoNi phase (due to heat treatment at 650C), consisting of spherical nanoparticles (~ 6 nm) with tendency to spherical agglomerates formation. Those nanosized magnetic particles (characterized by the single domain magnetic structure and blocking temperature TB below room temperature), located at MgB2 grain boundaries, could serve as effective magnetic pinning centers in MgB2, thus improving its electromagnetic properties.

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Enhancement of the critical current density in MgB₂wires doped with Ni nanoparticles

Cited by 19 publications

References 41 publications

Effect of excess Mg and nano-additives on the superconducting properties of weakly connected bulk MgB2

Effect of excess Mg and nano-additives on the superconducting properties of weakly connected bulk MgB2

Enhancing superconducting properties of MgB₂pellets by addition of amorphous magnetic Ni–Co–B nanoparticles

Microstructural Features of Magnetic NiCoB Nanoparticles Addition to MgB2 Precursor Powders

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Enhancement of the critical current density in MgB2wires doped with Ni nanoparticles

Cited by 19 publications

References 41 publications

Effect of excess Mg and nano-additives on the superconducting properties of weakly connected bulk MgB2

Effect of excess Mg and nano-additives on the superconducting properties of weakly connected bulk MgB2

Enhancing superconducting properties of MgB2pellets by addition of amorphous magnetic Ni–Co–B nanoparticles

Microstructural Features of Magnetic NiCoB Nanoparticles Addition to MgB2 Precursor Powders

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Product

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Enhancement of the critical current density in MgB₂wires doped with Ni nanoparticles

Enhancing superconducting properties of MgB₂pellets by addition of amorphous magnetic Ni–Co–B nanoparticles