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Superconductor dynamics

Superconductor dynamics. Fedor Gömöry Institute of Electrical Engineering Slovak Academy of Sciences Dubravska cesta 9, 84101 Bratislava, Slovakia elekgomo@savba.sk www.elu.sav.sk. m. I. S. Some useful formulas: magnetic moment of a current loop [Am 2 ]

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Superconductor dynamics

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  1. Superconductor dynamics Fedor Gömöry Institute of Electrical Engineering Slovak Academy of Sciences Dubravska cesta 9, 84101 Bratislava, Slovakia elekgomo@savba.sk www.elu.sav.sk

  2. m I S Some useful formulas: magnetic moment of a current loop [Am2] magnetization of a sample [A/m] alternative (preferred in [T] SC community) Measurable quantities: magnetic field B [T] – Hall probe, NMR voltage from a pick-up coil [V] Y average of magnetic field ui area of single turn linked magnetic flux number of turns

  3. Outline: 1. Hard superconductor in varying magnetic field Magnetization currents: Flux pinning Coupling currents 3. Possibilities for reduction of magnetization currents 4. Methods to measure magnetization and AC loss

  4. Outline: 1. Hard superconductor in varying magnetic field Magnetization currents: Flux pinning Coupling currents 3. Possibilities for reduction of magnetization currents 4. Methods to measure magnetization and AC loss

  5. Superconductors used in magnets - what is essential? type II. superconductor (critical field) high transport current density

  6. 0 0 0 0 0 0 0 Superconductors used in magnets - what is essential? type II. superconductor (critical field) mechanism(s) hindering the change of magnetic field distribution => pinning of magnetic flux = hard superconductor gradient in the flux density pinning of flux quanta distribution persists in static regime (DC field), but would require a work to be changed => dissipation in dynamic regime

  7. (repulsive) interaction of flux quanta => flux line lattice summation of microscopic pinning forces + elasticity of the flux line lattice = macroscopic pinning force density Fp [N/m3] macroscopic behavior described by the critical state model [Bean 1964]: local density of electrical current in hard superconductor is either 0 in the places that have not experienced any electric field or the critical current density, jc , elsewhere in the simplest version (first approximation) jc =const.

  8. Outline: 1. Hard superconductor in varying magnetic field Magnetization currents: Flux pinning Coupling currents 3. Possibilities for reduction of magnetization currents 4. Methods to measure magnetization and AC loss

  9. I 0 A 20 A 100 A Transport of electrical current e.g. the critical current measurement 80 A 20 A 0 A

  10. I 0 A 20 A 100 A j =+ jc j =0 Transport of electrical current e.g. the critical current measurement 80 A 20 A 0 A

  11. I 0 A 20 A 100 A j =+ jc j =0 Transport of electrical current e.g. the critical current measurement 80 A 20 A 0 A

  12. I 0 A 20 A 100 A j =+ jc j =0 Transport of electrical current e.g. the critical current measurement 80 A 20 A 0 A j =- jc

  13. I 0 A 20 A 100 A j =+ jc j =0 Transport of electrical current e.g. the critical current measurement 80 A 20 A 0 A j =- jc

  14. I 0 A 20 A 100 A j =+ jc j =0 Transport of electrical current e.g. the critical current measurement 80 A 20 A 0 A j =- jc persistent magnetization current

  15. Transport of electrical current AC cycle with Ialess than Ic: neutral zone persistent magnetization current 80  60  -80  -60  0 A

  16. neutral zone: j =0, E = 0  AC transport in hard superconductor is not dissipation-less (AC loss) U check for hysteresis in I vs.  plot

  17. AC transport loss in hard superconductor hysteresis  dissipation  AC loss

  18. Hard superconductor in changing magnetic field 0  30  50  40 mT  0  -50  -40  0  50 mT

  19. Hard superconductor in changing magnetic field 0  30  50  40 mT  0  -50  -40  0  50 mT

  20. Hard superconductor in changing magnetic field 0  30  50  40 mT  0  -50  -40  0  50 mT

  21. Hard superconductor in changing magnetic field 0  30  50  40 mT  0  -50  -40  0  50 mT

  22. Hard superconductor in changing magnetic field 0  30  50  40 mT  0  -50  -40  0  50 mT

  23. Hard superconductor in changing magnetic field 0  30  50  40 mT  0  -50  -40  0  50 mT

  24. Hard superconductor in changing magnetic field 0  30  50  40 mT  0  -50  -40  0  50 mT

  25. Hard superconductor in changing magnetic field dissipation because of flux pinning volume loss density Q [J/m3] magnetization: (2D geometry) Ba y x

  26. Round wire from hard superconductor in changing magnetic field Ms Bp Mssaturation magnetization, Bp penetration field

  27. Round wire from hard superconductor in changing magnetic field estimation of AC loss at Ba >> Bp

  28. (infinite) slab in parallel magnetic field – analytical solution B penetration field w for Ba<Bp j for Ba>Bp

  29. Slab in parallel magnetic field – analytical solution 3

  30. Outline: 1. Hard superconductor in varying magnetic field Magnetization currents: Flux pinning Coupling currents 3. Possibilities for reduction of magnetization currents 4. Methods to measure magnetization and AC loss

  31. Ba coupling currents Two parallel superconducting wires in metallic matrix in the case of a perfect coupling: 0  20  80  60 mT

  32. uncoupled: Magnetization of two parallel wires coupled:

  33. uncoupled: Magnetization of two parallel wires coupled: how to reduce the coupling currents ?

  34. lp j good interfaces bad interfaces Composite wires – twisted filaments

  35. coupling currents (partially) screen the applied field Bext Bi t  - time constant of the magnetic flux diffusion A.Campbell (1982) Cryogenics 22 3 K. Kwasnitza, S. Clerc (1994) Physica C 233 423 K. Kwasnitza, S. Clerc, R. Flukiger, Y. Huang (1999) Cryogenics 39 829 Composite wires – twisted filaments shape factor (~ aspect ratio) in AC excitation round wire

  36. Outline: 1. Hard superconductor in varying magnetic field Magnetization currents: Flux pinning Coupling currents 3. Possibilities for reduction of magnetization currents 4. Methods to measure magnetization and AC loss

  37. width of superconductor (perpendicular to the applied magnetic field) Persistent currents: at large fields proportional to Bp ~ jc w = magnetization reduction by either lower jcor reduced w lowering of jcwould mean more superconducting material required to transport the same current thus only plausible way is the reduction of w

  38. effect of the field orientation perpendicular field parallel field

  39. H H Magnetization loss in strip with aspect ratio 1:1000 B B Ba/m0 [A/m]

  40. B B in the case of flat wire or cable the orientation is not a free parameter = reduction of the width e.g. striation of CC tapes ~ 6 times lower magnetization

  41. B B striation of CC tapes but in operation the filaments are connected at magnet terminations coupling currents will appear => transposition necessary

  42. transposition length effective transverse resistivity Coupling currents: at low frequencies proportional to the time constant of magnetic flux diffusion = filaments (in single tape) or strands (in a cable) should be transposed = low loss requires high inter-filament or inter-strand resistivity but good stability needs the opposite

  43. Outline: 1. Hard superconductor in varying magnetic field Magnetization currents: Flux pinning Coupling currents 3. Possibilities for reduction of magnetization currents 4. Methods to measure magnetization and AC loss

  44. Different methods necessary to investigate • Wire (strand, tape) • Cable • Magnet shape of the excitation field (current) pulse transition unipolar harmonic relevant information can be achieved in harmonic regime final testing necessary in actual regime

  45. ideal magnetization loss measurement:

  46. pick-up coil wrapped around the sample induced voltageum(t) in one turn: um Area S pick-up coil voltage processed by integration either numerical or by an electronic integrator:

  47. M  =   = /2 B  = 3/2  = 0 Method 1: double pick-up coil system with an electronic integrator : measuring coil, compensating coil um uM uc M AC loss in one magnetization cycle [J/m3]:

  48. ” T ’ -1 Harmonic AC excitation – use of complex susceptibilities Temperature dependence: fundamental component n =1 AC loss per cycle energy of magnetic shielding

  49. Method 2: Lock-in amplifier – phase sensitive analysis of voltage signal spectrum in-phase and out-of-phase signals reference signal necessary to set the frequency phase taken from the current energizing the AC field coil reference um uM UnS Lock-in amplifier UnC uc

  50. Method 2: Lock-in amplifier – only at harmonic AC excitation empty coil sample magnetization fundamental susceptibility higher harmonic susceptibilities

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