A Proposal for a 50 T HTS Solenoid

1. A Proposal for a 50 T HTS Solenoid Steve Kahn Muons Inc. September 26, 2006 S. Kahn -- 50 T HTS Solenoid

2. Alternating Solenoid Lattice for Cooling • We plan to use high field solenoid magnets in the near final stages of cooling. • The need for a high field can be seen by examining the formula for equilibrium emittance: • The figure on the right shows a lattice for a 15 T alternating solenoid scheme previously studied. S. Kahn -- 50 T HTS Solenoid

3. From R. Palmer From R. Palmer S. Kahn -- 50 T HTS Solenoid

4. S. Kahn -- 50 T HTS Solenoid

5. A Proposal for a High Field Solenoid Magnet R&D • The availability of commercial high temperature superconductor tape (HTS) should allow significantly higher field that can produce smaller emittance muon beams. • HTS tape can carry significant current in the presence of high fields where Nb3Sn or NbTi conductors cannot. • We would like to see what we can design with this commercially available HTS tape. S. Kahn -- 50 T HTS Solenoid

6. Comparison of JE for HTS Conductors We have chosen to use Bi2223 since it is available as a reinforced tape from AMSC The conductor can carry significant current at very high fields. NbTi and Nb3Sn can not. S. Kahn -- 50 T HTS Solenoid

7. High Strength Tape used for calculations New and Improved High Strength Plus Tape Properties of American Superconductor’s High Temperature Superconductor Wire • 6% more current per turn • 10 % more turns per radial space S. Kahn -- 50 T HTS Solenoid

8. Cross Sections of AMSC HTS Tape High Current Tape High Compression Tape High Strength Tape React and Wind S. Kahn -- 50 T HTS Solenoid

9. Some Mechanical Properties of Oxford BSSCO-2212 Strain Degradation at 0.4% Wind and React Ultimate Strength~130 MPa Young’s Modulus E~51-63 GPa S. Kahn -- 50 T HTS Solenoid

10. Why Do We Want to Go to Liquid Helium? The parallel field orientation is the most relevant for a solenoid magnet. Previous calculations had used the perpendicular field. (We can view this not as a mistake, but as a contingency). S. Kahn -- 50 T HTS Solenoid

11. Current Carrying Capacity for HTS Tape in a Magnetic FieldScale Factor is relative to 77ºK with self field S. Kahn -- 50 T HTS Solenoid

12. Field Quadratic Linear 30 1.5378 1.5454 40 1.3091 1.3384 50 1.0685 1.1314 60 0.816 0.9244 Fit to High Field to Extrapolate Beyond 27 T • We are using BSSCO 2223 which has been measured only to 27 T in the perpendicular configuration. We are using it in the parallel configuration. • We have to extrapolate to high field. • We know that BSSCO 2212 has been tested to 45 T, so we think that the AMSC tape will work. • The high field measurements of BSSCO 2212 has a different falloff from BSSCO 2223. • We certainly will need measurements of the AMSC tape at high field S. Kahn -- 50 T HTS Solenoid

13. A Vision of a Very High Field Solenoid • Design for 50 Tesla. • Inner Aperture Radius: 2.5 cm. • Axial Length chosen: 1 meter • Use stainless steel ribbon between layers of HTS tape. • We will vary the thickness of the SS ribbon. • The SS ribbon provides additional tensile strength • HTS tape has 300 MPa max tensile strength. • SS-316 ribbon: choose 660 MPa (Goodfellow range for strength is 460-860 MPa) • Composite strength = SS SS + (1-SS) HTS (adds like parallel springs). • We use the Jeff associated to 50 Tesla. • We operate at 85% of the critical current. • All parameters used come from American Superconductor’s Spec Sheets. S. Kahn -- 50 T HTS Solenoid

14. Constraining Each Layer With A Stainless Steel Strip • Instead of constraining the forces as a single outer shell where the radial forces build up to the compressive strain limit, we can put a mini-shell with each layer. Suggested by R. Palmer, but actually implemented previously by BNL’s Magnet Division for RIA magnet. (See photo) S. Kahn -- 50 T HTS Solenoid

15. A Slightly More Aggressive Approach • We can vary the amount of stainless steel interleafing as a function of radius to achieve 0.4% strain. • At small radius where we have smaller stress, we could use a smaller fraction of stainless steel. (See previous slide) • In the middle radial region we would use more stainless where the tensile strength is largest. • Following this approach we can build a 50 Tesla solenoid. • Case 3: 50 Tesla solenoid with SS interleaving varied to achieve 0.4% strain throughout. • A 60 Tesla solenoid may be achieved by increasing the current as the field falls off with radius by using independent power supplies for different radial regions. S. Kahn -- 50 T HTS Solenoid

16. Varying SS Interleaving to Achieve Maximum Strain • The thickness of the stainless steel interleaving is varied as a function of radius so as to reach the maximum allowable strain through out the magnet. • This minimizes the outer solenoid radius (and consequently the conductor costs). • This also brings the center of current closer to the axis and reduces the stored energy. • This is likely to increase the mechanical problems. S. Kahn -- 50 T HTS Solenoid

17. Case Comparisons • The tables on the left summarize the parameters and results of the three cases presented. • The analysis assumes the solenoid length is 70 cm • (We are now using a 1 m length.) • The top table shows the dimensional parameters: • Inner/outer radius • Conductor length and amp-turns. • The bottom table shows the results from the magnetic properties: • Stored energy • Radial and Axial Forces S. Kahn -- 50 T HTS Solenoid

18. Comments on Stored Energy • The 70 cm length was chosen to be consistent with the range of ~100 MeV muon. It is also the minimum solenoid length where there is some “non-fringing” central field. • The stored energy of the 50 Tesla magnet (case 3) is 20 Mega-Joules (for 70 cm). • This can be compared to 7 Mega-Joules for the 10 m long LHC 2-in-one dipole. • The LHC quench protection system actually handles a string of dipoles in a sextant (?). • There are differences between HTS and NbTi that need to be considered for quench protection. • HTS goes resistive at a slower rate than NbTi. • A quench propagates at a slower velocity in HTS than for NbTi. • We will have to perform computer simulations of quench protection for the HTS system to determine how to protect the magnet in case of an incident. S. Kahn -- 50 T HTS Solenoid

19. What about Axial Forces? • There is a significant contribution to the axial forces from the fringing radial fields at the ends. • In the 50 Tesla solenoid shown we will see a fringing field of 9 Tesla • We have seen that there is a total axial compressive force at the center of ~30 Mega-Newtons. S. Kahn -- 50 T HTS Solenoid

20. More on Compressive Forces • The top figure shows the Lorentz force density at the end of the solenoid as a function of radius for the three cases. • The axial pressure on the end is P=JBrt where t is the tape width. This peaks at 10 MPa. • The lower figure shows the Lorentz force density along the length for the peak radial position. • It is largest at the end and falls to zero at center as expected. • These stresses are not large. Do we have to worry about compressive strain along the axial direction? • The maximum allowable compressive strain for the tape is 0.15%. S. Kahn -- 50 T HTS Solenoid

21. Formulate R&D Plan • Initial measurements of material properties. • JC measurements under tensile and compressive strain. • Modulus measurements of conductor. • Thermal cycling to 4K. • Formulate and prepare inserts for high field tests. • Design insert for test in 30 Tesla magnet. • This magnet has a reasonable size aperture. • At 30 Tesla, some part of the insert should be at the strain limit. • Program for conductor tests at 45 Tesla. • 45 Tesla magnet has limited aperture (3.1 cm). • It has a warm aperture. • There is a 38 Tesla facility in Japan that could be used if the 45 Tesla facility is not available. S. Kahn -- 50 T HTS Solenoid

22. Preliminary Calculations for Quench Protection • I am presenting some preliminary calculations using the quench calculation program QUENCH. • This program was written by Martin Wilson at Rutherford Lab in the 1970’s. The current version of the program is marketed by B. Hassenzahl of Advanced Energy Analysis. BNL has a license to use it. • There are other codes available: • QUENCHPRO at FNAL Technical Division. • SPQR from CERN. • Vector Fields is developing a quench propagation code ?? S. Kahn -- 50 T HTS Solenoid

23. Conductor and Insulator Description • The conductor is BSCCO 2223 which is 30% HTS filaments and 70% Ag matrix and Ag-Mg sheath (for strength). We assume the matrix/sheath is all Ag for the calculation. • The insulator is assumed to be the Stainless Steel interleaving. A minimum thickness (0.07 mm) is used since we are describing the inner layers. • In practice we will likely add a ceramic coating or kapton wrap as insulator. This will inhibit the transverse quench propagation. S. Kahn -- 50 T HTS Solenoid

24. Conductor Material Properties Necessary for Quench Protection • We need the material properties of all the components of the conductor and insulation. • The important properties are • Heat capacitance (Specific Heat) • Resistivity • Thermal conductance • Obtained from resistivity with Wiedemann-Frantz law. • CV and  are parameterized as in up to four temperature ranges: S. Kahn -- 50 T HTS Solenoid

25. Critical Current Measurements Used only high field part of data to determine Bc20 • Measurements of critical current as a function of B and temperature are from EHTS (another provider of BSSCO 2223). • The measured data is used to determine parameters of the following equation: S. Kahn -- 50 T HTS Solenoid

26. T1 Ts T0 Lorentz Number Quench Propagation Velocity • Quench protection calculations depend on the quench propagation velocity. • The quench propagation velocity can be calculated from the formula below. • This is what I did. • Experience for NbTi shows that the formula does not reproduce the measurements. • Typically the experimentally determined value is used. • We need to measure this for HTS. • One of the weaknesses of the velocity calculation is that the specific heat (CV) varies as T3 and is rapidly varying at the quench front. S. Kahn -- 50 T HTS Solenoid

27. Circuit for Quench Energy Extraction • Quench circuit components: • Solenoid represented by inductance L. Also there is an internal resistance (not shown) which is about 10 ohm. • RPR represents the energy extraction resistance. This will take the large share of quench energy. • Switch will be activated by quench detection system. • Could even be a diode system. • REXT represents the resistance associated to leads, power supply, etc. Power Supply RSW RPR L REXT Solenoid Magnet S. Kahn -- 50 T HTS Solenoid

28. Circuit Parameters • QUENCH treats the whole magnet. It does not provide for segmenting the magnet into separate coupled systems. • The total inductance can be calculated from the stored energy: • U=½LI2 where U=20 Mega-Joules and I is the total amp-turns(=2.97107). • There are 444 layers  175 turns/layer = 77625 turns. • This gives 280 henrys (big!) • The resistance associated with 61 km of Ag is 8 ohms. • We certainly will need to trigger an external resistance into the circuit with a quench is detected. S. Kahn -- 50 T HTS Solenoid

29. Quench Parameters as a Function of External Resistance • The figures show the following parameters • as a function of an external resistance for • energy extraction. • Maximum temperature on conductor • Time constant for decay • External voltage on external resistance • Note that as one increases the external • resistance one decreases temperature, but • increases the external voltage. S. Kahn -- 50 T HTS Solenoid

30. A Better Approach • It may be a better approach to divide the magnet radial into separate thermally and electrically isolated systems on separate power supplies. These systems would be coupled through mutual inductance. • Each system would contain less stored energy and could have different time constants and different start times. • Different sub-systems would have different critical currents since they are at different magnetic fields. Some may not quench at all. • QUNECH can not simply handle this complex system. • Do the other codes handle this or do we have to write our own? • Fermilab people may have thought about this. S. Kahn -- 50 T HTS Solenoid

31. What Do We Need to Measure? • It is clear from this initial calculation that some parameters are not well known. We should try to measure them. • Electrical resistivity and heat capacity of HTS conductor as a function of temperature. This should be done above critical current. • Same measurements of Silver as a control. • Determine Ic(B) at high field. Verify that the critical current relation that we used (which was developed for NbTi, Nb3Sn) works for HTS. • Measure the quench propagation velocity. This is important. S. Kahn -- 50 T HTS Solenoid