D C van der Laan scite author profile

A remarkably large reversible reduction in the critical current of "second generation" high-temperature superconductors for electric power applications has been measured with a new technique over a wide range of mechanical strain. The effect amounts to a 40% reduction in critical current at 1% compressive strain in self-magnetic field, and is symmetric for compressive and tensile strains. The intrinsic effect is measured in highly aligned multigranular YBa 2 Cu 3 O 7−d coated conductors made by different processes, including superconductors with nanoscale pinning centers. This effect and its magnitude are expected to have a significant impact on power applications and provide a useful new parameter for probing the fundamental nature of current transport in high-temperature superconductors.

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Effect of strain, magnetic field and field angle on the critical current density of Y Ba₂Cu₃O_7−δcoated conductors

Laan

Ekin

Douglas

et al. 2010

Supercond. Sci. Technol.

128

123

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A large, magnetic-field-dependent, reversible reduction in critical current density with axial strain in YBa 2 Cu 3 O 7−δ coated conductors at 75.9 K has been measured. This effect may have important implications for the performance of YBa 2 Cu 3 O 7−δ coated conductors in applications where the conductor experiences large stresses in the presence of a magnetic field. Previous studies have been performed only under tensile strain and could provide only a limited understanding of the in-field strain effect. We now have constructed a device for measuring the critical current density as a function of axial compressive and tensile strain and applied magnetic field as well as magnetic field angle, in order to determine the magnitude of this effect and to create a better understanding of its origin. The reversible reduction in critical current density with strain becomes larger with increasing magnetic field at all field angles. At 76 K the critical current density is reduced by about 30% at −0.5% strain when a magnetic field of 5 T is applied parallel to the c-axis of the conductor or 8 T is applied in the ab-plane, compared to a reduction of only 13% in self-field. Differences in the strain response of the critical current density at various magnetic field angles indicate that the pinning mechanisms in YBa 2 Cu 3 O 7−δ coated conductors are uniquely affected by strain.

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Introduction of CORC^®wires: highly flexible, round high-temperature superconducting wires for magnet and power transmission applications

Weiss

Mulder

Kate

et al. 2016

Supercond. Sci. Technol.

190

124

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Conductor on Round Core (CORC®) technology has achieved a long sought-after benchmark by enabling the production of round, multifilament, (RE)Ba 2 Ca 3 O 7-x coated conductors with practical current densities for use in magnets and power applications. Recent progress, including the demonstration of engineering current density beyond 300 Amm-2 at 4.2 K and 20 T, indicates that CORC® cables are a viable conductor for next generation high field magnets. Tapes with 30 µm substrate thickness and tape widths down to 2 mm have improved the capabilities of CORC® technology by allowing the production of CORC® wires as thin as 3 mm in diameter with the potential to enhance the engineering current density further. An important benefit of the thin CORC® wires is their improved flexibility compared to thicker (7 to 8 mm diameter) CORC® cables. Critical current measurements were carried out on tapes extracted from CORC® wires made using 2 and 3 mm wide tape after bending the wires to various diameters from 10 cm to 3.5 cm. These thin wires are highly flexible and retain close to 90 % of their original critical current even after bending to a diameter of 3.5 cm. A small 5-turn solenoid was constructed and measured as a function of applied magnetic field, exhibiting an engineering current density of 233 Amm-2 at 4.2 K and 10 T. CORC® wires thus form an attractive solution for applications between 4.2 K and 77 K, including high-field magnets that require high current densities with small bending diameters, benefiting from a ready-to-use form (similar to NbTi and contrary to Nb 3 Sn wires) that does not require additional processing following coil construction.

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D C van der Laan

Large intrinsic effect of axial strain on the critical current of high-temperature superconductors for electric power applications

Effect of strain, magnetic field and field angle on the critical current density of Y Ba₂Cu₃O_7−δcoated conductors

Introduction of CORC^®wires: highly flexible, round high-temperature superconducting wires for magnet and power transmission applications

Contact Info

Product

Resources

About

D C van der Laan

Large intrinsic effect of axial strain on the critical current of high-temperature superconductors for electric power applications

Effect of strain, magnetic field and field angle on the critical current density of Y Ba2Cu3O7−δcoated conductors

Introduction of CORC®wires: highly flexible, round high-temperature superconducting wires for magnet and power transmission applications

Contact Info

Product

Resources

About

Effect of strain, magnetic field and field angle on the critical current density of Y Ba₂Cu₃O_7−δcoated conductors

Introduction of CORC^®wires: highly flexible, round high-temperature superconducting wires for magnet and power transmission applications