Critical Current and Microstructure of FeSe Wires and Tapes Prepared by PIT Method

Critical Current and Microstructure of FeSe Wires and Tapes Prepared by PIT Method

The FeSe wires and tapes with Fe (S22 steel) and Cu/Nb sheath were fabricated by various modifications of the powder-in-tube (PIT) method. The superconducting critical parameters (upper critical field, critical current, critical temperature) depending on heat treatment time were investigated using r...

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Veröffentlicht in:IEEE transactions on applied superconductivity 2019-04, Vol.29 (3), p.1-5
Hauptverfasser: Vlasenko, Vladimir A., Pervakov, Kirill S., Eltsev, Yuri F., Berbentsev, Vladimir D., Tsapleva, Anastasiia S., Lukyanov, Pavel A., Abdyukhanov, Ildar M., Pudalov, Vladimir M.
Format: Artikel
Sprache:eng
Schlagworte:
Annealing
Copper
Critical current (superconductivity)
critical current density
Critical current density (superconductivity)
Critical field (superconductivity)
Crystal structure
Fine grinding
Heat treatment
iron-based superconductor
Niobium
niobium barrier
Parameter modification
Phase transitions
powder-in-tube
Sheaths
Superconducting filaments and wires
Superconducting magnets
Superconducting tapes
superconducting wires
Superconductivity
Temperature measurement
Wire
Wires
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container_issue 3
container_start_page 1
container_title IEEE transactions on applied superconductivity
container_volume 29
creator Vlasenko, Vladimir A.
Pervakov, Kirill S.
Eltsev, Yuri F.
Berbentsev, Vladimir D.
Tsapleva, Anastasiia S.
Lukyanov, Pavel A.
Abdyukhanov, Ildar M.
Pudalov, Vladimir M.
description The FeSe wires and tapes with Fe (S22 steel) and Cu/Nb sheath were fabricated by various modifications of the powder-in-tube (PIT) method. The superconducting critical parameters (upper critical field, critical current, critical temperature) depending on heat treatment time were investigated using resistive R (T) and transport measurements I (V) in magnetic fields up to 9T. The low-temperature annealing up to 72 h improve superconducting properties of superconducting wire with steel sheath. However, the annealing is the cause of superconducting wires degradation due to deterioration of contacts between the steel shell and the FeSe core. We show that industrial PIT technology of manufacturing \text{Nb}_3\text{Sn} wires and tapes might be adopted for iron-based superconductors. Moreover, industrial PIT is a promising technique for fabricating large scale and high-quality superconducting wire and tapes. In addition, we show that fine grinding of the FeSe bulks leads mainly to a phase transition from the tetragonal to the hexagonal crystal structure that exhibits no superconductivity.
doi_str_mv 10.1109/TASC.2019.2902362
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The superconducting critical parameters (upper critical field, critical current, critical temperature) depending on heat treatment time were investigated using resistive R (T) and transport measurements I (V) in magnetic fields up to 9T. The low-temperature annealing up to 72 h improve superconducting properties of superconducting wire with steel sheath. However, the annealing is the cause of superconducting wires degradation due to deterioration of contacts between the steel shell and the FeSe core. We show that industrial PIT technology of manufacturing &lt;inline-formula&gt;&lt;tex-math notation="LaTeX"&gt;\text{Nb}_3\text{Sn}&lt;/tex-math&gt;&lt;/inline-formula&gt; wires and tapes might be adopted for iron-based superconductors. Moreover, industrial PIT is a promising technique for fabricating large scale and high-quality superconducting wire and tapes. 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The superconducting critical parameters (upper critical field, critical current, critical temperature) depending on heat treatment time were investigated using resistive R (T) and transport measurements I (V) in magnetic fields up to 9T. The low-temperature annealing up to 72 h improve superconducting properties of superconducting wire with steel sheath. However, the annealing is the cause of superconducting wires degradation due to deterioration of contacts between the steel shell and the FeSe core. We show that industrial PIT technology of manufacturing &lt;inline-formula&gt;&lt;tex-math notation="LaTeX"&gt;\text{Nb}_3\text{Sn}&lt;/tex-math&gt;&lt;/inline-formula&gt; wires and tapes might be adopted for iron-based superconductors. Moreover, industrial PIT is a promising technique for fabricating large scale and high-quality superconducting wire and tapes. In addition, we show that fine grinding of the FeSe bulks leads mainly to a phase transition from the tetragonal to the hexagonal crystal structure that exhibits no superconductivity.</description><subject>Annealing</subject><subject>Copper</subject><subject>Critical current (superconductivity)</subject><subject>critical current density</subject><subject>Critical current density (superconductivity)</subject><subject>Critical field (superconductivity)</subject><subject>Crystal structure</subject><subject>Fine grinding</subject><subject>Heat treatment</subject><subject>iron-based superconductor</subject><subject>Niobium</subject><subject>niobium barrier</subject><subject>Parameter modification</subject><subject>Phase transitions</subject><subject>powder-in-tube</subject><subject>Sheaths</subject><subject>Superconducting filaments and wires</subject><subject>Superconducting magnets</subject><subject>Superconducting tapes</subject><subject>superconducting wires</subject><subject>Superconductivity</subject><subject>Temperature measurement</subject><subject>Wire</subject><subject>Wires</subject><issn>1051-8223</issn><issn>1558-2515</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2019</creationdate><recordtype>article</recordtype><sourceid>RIE</sourceid><recordid>eNo9kMFOwzAQRC0EEqXwAYiLJc4JXjt27GMVUajUiooGcbRcZyNSlSY4yaF_T0IrLrtzeDOrHULugcUAzDzls00WcwYm5oZxofgFmYCUOuIS5OWgmYRIcy6uyU3b7hiDRCdyQt6zUHWVd3ua9SHgoaPuUNBV5UPddqH3XR-Q1iWd4wbpZxWw_QNy1wxqHbBxAQu6PdL1Iqcr7L7q4pZclW7f4t15T8nH_DnPXqPl28simy0jz43oogQ8V7A1w3BaJB40Z8KLdOsKMCVTJTOYGHAOU2VSqYpUpynolBslRZl4MSWPp9wm1D89tp3d1X04DCct54xpUIyZgYITNX7UBixtE6pvF44WmB2rs2N1dqzOnqsbPA8nT4WI_7xWUskh8Rc3c2ey</recordid><startdate>20190401</startdate><enddate>20190401</enddate><creator>Vlasenko, Vladimir A.</creator><creator>Pervakov, Kirill S.</creator><creator>Eltsev, Yuri F.</creator><creator>Berbentsev, Vladimir D.</creator><creator>Tsapleva, Anastasiia S.</creator><creator>Lukyanov, Pavel A.</creator><creator>Abdyukhanov, Ildar M.</creator><creator>Pudalov, Vladimir M.</creator><general>IEEE</general><general>The Institute of Electrical and Electronics Engineers, Inc. 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The superconducting critical parameters (upper critical field, critical current, critical temperature) depending on heat treatment time were investigated using resistive R (T) and transport measurements I (V) in magnetic fields up to 9T. The low-temperature annealing up to 72 h improve superconducting properties of superconducting wire with steel sheath. However, the annealing is the cause of superconducting wires degradation due to deterioration of contacts between the steel shell and the FeSe core. We show that industrial PIT technology of manufacturing &lt;inline-formula&gt;&lt;tex-math notation="LaTeX"&gt;\text{Nb}_3\text{Sn}&lt;/tex-math&gt;&lt;/inline-formula&gt; wires and tapes might be adopted for iron-based superconductors. Moreover, industrial PIT is a promising technique for fabricating large scale and high-quality superconducting wire and tapes. 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subjects Annealing
Copper
Critical current (superconductivity)
critical current density
Critical current density (superconductivity)
Critical field (superconductivity)
Crystal structure
Fine grinding
Heat treatment
iron-based superconductor
Niobium
niobium barrier
Parameter modification
Phase transitions
powder-in-tube
Sheaths
Superconducting filaments and wires
Superconducting magnets
Superconducting tapes
superconducting wires
Superconductivity
Temperature measurement
Wire
Wires
title Critical Current and Microstructure of FeSe Wires and Tapes Prepared by PIT Method
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