Massachusetts Institute of Technology 22.68J/2.64J Superconducting Magnets ⇓ April 10, 2003 •Lecture #7 – Magnetic Instabilities ¾Flux Flow; Bean’s Critical State Model ¾Magnetization; Flux Jumping
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Massachusetts Institute of Technology22.68J/2.64J
Superconducting Magnets
⇓
April 10, 2003
•Lecture #7 – Magnetic Instabilities¾Flux Flow; Bean’s Critical State Model ¾Magnetization; Flux Jumping
Magnetic Instabilities
• motion in Type II superconductors
→ Flux Flow Resistivity
and nature of magnetic instability
“critical state”
hysteresis losses in changing magnetic fields
Derive from dissipative nature of flux
• Flux Flow – Key to understanding dissipation, local heating,
– Requires understanding of the concept of the
– Leads to understanding of magnetization and
Measured Flux Penetrationin a Type II Superconductor
Flux Enters in Quantized Vortices
Technical Type II SuperconductorsDisplay a Magnetic Hysteresis
M ∝ Jc
Area Under Magnetization Loop is Proportional to Dissipated Energy/cycle ∝ ∆B Jc deff
Measured Flux Jumps in a Magnetization Loop
Fine Filaments in Nb3Sn
CICC
Strand (0.81 mm diameter) Sub-element
Bundle
Superconducting Filament(50 mm x 50mm) (~3 µm diameter)
Relevant Superconducting Wires are Complex Composites
Typical SSC Nb-47wt.%Ti Typical reacted ITER Nb3Snstrand (OST manufacture). strand (IGC manufacture).
Flux Jump Stability of High Temperature Superconductors
AC LossesTwisting the superconducting filaments in the composite wire is necessary to
electrodynamically decouple them
∝ (~1 µm)
∝ strand diameter )
∝ )2
Hysteresis losses filament diameter
Hysteresis losses
(~1 mm
Twisting filaments also necessary to reduce coupling losses Power dissipation (Twist Pitch
NbTi Billet Assembly
HTS Tape (BSCCO)
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