Formation of High-Field Pinning Centers in Superconducting MgB2 Wires by Using High Hot Isostatic Pressure Process

Gajda, D.; Morawski, A.; Zaleski, A.; Akdoğan, Mustafa; Yetiş, H.; Karaboğa, Fırat; Cetner, T.; Belenli, I.

doi:10.1007/s10948-017-4161-y

Cited by 20 publications

(10 citation statements)

References 25 publications

(37 reference statements)

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“…This method is used in superconducting materials with a high irreversible magnetic field. The value of B irr is dependent on high-field pinning centers [39,62,70,71]. The results in Ref.…”

Section: Discussionmentioning

confidence: 91%

“…Hot isostatic pressing (HIP) significantly increases the number of high-field pinning centers, e.g., increase in the density of dislocations, and accelerates the substitution of C for B, allowing to obtain a uniform distribution of pinning centers [27,31,35,36]. In addition, results indicate that using boron grains with nanosizes makes it possible to obtain more high-field pinning centers than usage of large particles of boron [70,71]. Studies also showed that high isostatic pressure increases the number of connections between the grains densifying material [31,36].…”

Section: Physical Properties and Pinning Centers In Mgb 2 Wiresmentioning

confidence: 99%

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Analysis Method of High-Field Pinning Centers in NbTi Wires and MgB2 Wires

Gajda

2018

J Low Temp Phys

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The main purpose of this article is to show an easier and more accurate method for analyzing high-field pinning centers. Previous methods did not allow for precise analysis and research on high-field pinning centers, they studied only the dominant pinning mechanism, and they required a maximum of pinning force (F pmax) to analyze pinning centers. The main advantage of this method can be used in samples without the maximum pinning force required by other methods to analyze the pinning mechanism. In addition, this method allows us to observe even small changes in the density of individual pinning centers. This method is based on analysis of critical current density values in different ranges of reduced magnetic field. The method of analysis of highfield pinning centers allows primarily to develop methods and directions for creation of high-field pinning centers. The surface pinning centers are strong pinning centers in low magnetic fields and very weak pinning centers in middle and high magnetic fields. Additionally, the analysis of pinning centers shows that dislocations, strains, substitutions in the crystal lattice, and precipitation inside the grains create strong pinning centers in high magnetic fields and very weak pinning centers in low and middle magnetic fields. Research indicates that strains, substitutions in the crystal lattice, and precipitates inside grains form pinning centers that operate in the high magnetic field range.

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“…This method is used in superconducting materials with a high irreversible magnetic field. The value of B irr is dependent on high-field pinning centers [39,62,70,71]. The results in Ref.…”

Section: Discussionmentioning

confidence: 91%

Section: Physical Properties and Pinning Centers In Mgb 2 Wiresmentioning

confidence: 99%

Analysis Method of High-Field Pinning Centers in NbTi Wires and MgB2 Wires

Gajda

2018

J Low Temp Phys

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“…Details of the production methods are presented in [21]. All samples were heated in an argon atmosphere at temperatures ranging from 680 • C to 740 • C, and under isostatic pressures ranging from 0.1 MPa to 1.1 GPa for 40 min, as listed in Table 1 [35].…”

Section: Methodsmentioning

confidence: 99%

Influence of Amorphous Boron Grain Size, High Isostatic Pressure, Annealing Temperature, and Filling Density of Unreacted Material on Structure, Critical Parameters, n-Value, and Engineering Critical Current Density in MgB2 Wires

et al. 2021

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Our results show that a lower density of unreacted Mg + B material during an Mg solid-state synthesis reaction leads to a significant reduction in the quantity of the superconducting phase and lowers the homogeneity of the superconducting material. It also significantly reduces the irreversible magnetic field (Birr), critical temperature (Tc), upper magnetic field (Bc2), engineered critical current density (Jec), and n-value, despite high isostatic pressure (HIP) treatment and the use of nanoboron in the sample. Our measurements show that samples with large boron grains with an 8% higher density of unreacted Mg + B material allow better critical parameters to be achieved. Studies have shown that the density of unreacted material has little effect on Birr, Tc, Bc2, Jec, and the n-value for an Mg liquid-state synthesis reaction. The results show that the critical parameters during an Mg liquid-state synthesis reaction depend mainly on grain size. Nanoboron grains allow for the highest Birr, Tc, Bc2, Jec, and n-values. Scanning electron microscopy (SEM) images taken from the longitudinal sections of the wires show that the samples annealed under low isostatic pressure have a highly heterogeneous structure. High isostatic pressure heat treatment greatly improves the homogeneity of MgB2.

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“…Small grains of amorphous boron increase the rate of synthesis reaction and lead to an increase in J c and B irr [21,22]. Gajda et al indicate that a high pressure of 1.1 GPa allows for a more efficient increase in the density of high-field pinning centers in in situ MgB 2 wires with nano-amorphous boron [4] than with big amorphous boron [23]. The crystalline Research (PAS) [16].…”

Section: Methodsmentioning

confidence: 99%

“…Dislocations and strains in superconducting wires can be created by cold treatment (e.g., cold isostatic pressure [2], cold drawing [3]) or hot treatment (e.g., hot isostatic pressure process which creates dislocations [4]) and also by the shrinkage of the superconducting material during the synthesis reaction [5] or substitution into crystal lattice, which creates strains in either case [6]. Dislocations created by cold treatment disappear as a result of thermal processes.…”

Section: Introductionmentioning

confidence: 99%

The Impact of High Pressure, Doping and the Size of Crystalline Boron Grains on Creation of High-Field Pinning Centers in In Situ MgB2 Wires

Majchrzak

Zaleski

Morawski

et al. 2018

J Supercond Nov Magn

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In this work, we investigated the influence of isostatic pressure (of 0.1 MPa and 1.1 GPa) during heat treatment, doping, size and shape of crystalline boron grains, and annealing time at low annealing temperature (570 • C) on the formation of highfield pinning centers in MgB 2 wires. The results indicate that high isostatic pressure (1.1 GPa) at low annealing temperature (570 • C) and annealing time of 120 min significantly increases the density of high-field pinning centers in MgB 2 wires with small and large boron grains. Transport measurements show that an increase of annealing time from 120 to 210 min at 1.1 GPa slightly decreases the critical current density (J c ) and irreversibility field (B irr ) in MgB 2 wires with large boron grains, suggesting that longer annealing time weakly affects the density of high-field pinning centers. On the other hand, for MgB 2 wires with small boron grains, the annealing time of 210 min significantly reduces J c and B irr . This indicates that the longer annealing time at 1.1 GPa significantly reduces the density of high-field pinning centers. Our studies indicate that dislocations created by the hot isostatic pressure process significantly increase B irr in the temperature range from 5 to 12 K. On the other hand, strains due to the shrinkage of MgB 2 material increase B irr in the temperature range from 12 to 34 K. The results show that small grains of crystalline boron and high isostatic pressure lead to a high density of dislocations and strains during transformation to the MgB 2 phase.

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Formation of High-Field Pinning Centers in Superconducting MgB2 Wires by Using High Hot Isostatic Pressure Process

Cited by 20 publications

References 25 publications

Analysis Method of High-Field Pinning Centers in NbTi Wires and MgB2 Wires

Analysis Method of High-Field Pinning Centers in NbTi Wires and MgB2 Wires

Influence of Amorphous Boron Grain Size, High Isostatic Pressure, Annealing Temperature, and Filling Density of Unreacted Material on Structure, Critical Parameters, n-Value, and Engineering Critical Current Density in MgB2 Wires

The Impact of High Pressure, Doping and the Size of Crystalline Boron Grains on Creation of High-Field Pinning Centers in In Situ MgB2 Wires

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