ISIS Related Issues for MICE

1. ISIS Related Issues for MICE Adam Dobbs Proton Accelerator Development Meeting, RAL 24th March 2011 A. Dobbs

2. Contents • Introduction to MICE • Purpose • Ionisation Cooling • The Cooling Channel • MICE in ISIS and the Beamline • ISIS beam loss measurement • ISIS beam loss and MICE particle rate • Beam loss and target depth • Beam loss and particle rate • Beam loss and muon rate • Conclusion A. Dobbs

3. Muon Ionisation Cooling Experiment • Purpose: investigate the feasibility of ionisation cooling, for application to a future Neutrino Factory or Muon Collider. • Neutrino Factory → Precision measurements of neutrino oscillations • Muon Collider → Multi-TeV lepton – anti-lepton collisions A. Dobbs

4. Ionisation Cooling - Why • An NF muon beam requires cooling (emittance reduction) in order to fit efficiently within the acceptance of downstream acceleration components • An MC also requires small interaction points to increase luminosity • Muon lifetime of 2.2μs to fast to permit traditional cooling techniques → ionisation cooling A. Dobbs

5. Ionisation Cooling - How • Pass the beam through an absorber e.g. liquid hydrogen, lithium hydride • The particle beam ionises the medium, the beam particles losing energy and momentum in all directions • Re-accelerate the beam in the beamline direction (z) only, using a radio frequency electric field v LiH2 RF v v A. Dobbs

6. MICE Step VI A. Dobbs

7. MICE in ISIS and the Beamline A. Dobbs

8. The MICE target • A 24 coil stator is used to drive a shuttle, consisting of a titanium shaft upon which are mounted permanent magnets to couple to the field produced by the stator • The lower end of the shaft takes the form of a hollow cylinder, which is pulsed into the ISIS beam by the stator • Upper and lower bearings are used to maintain the transverse position of the shaft. A. Dobbs

9. ISIS Beam loss • 39 argon gas ionisation chambers around the ring • Use the summed signal of the four sector 7 BLMs, integrate over the whole 10ms ISIS cycle (V.ms) • Slightly different gauge used than ISIS (smaller by ∼ 1/3 ) Increased beam loss levels raise the concerns over machine activation levels inhibiting hands-on maintenance A. Dobbs

10. Beam Loss and Target Depth A. Dobbs

11. Beam Loss and MICE Particle Rate • Linear correlation • Constant offset • Averaged data – few hundred pulses per point • Pion optics A. Dobbs

12. Beam Loss and MICE Particle Rate Spill-by-spill data (no averaging) -veπ→μ optics • +veπ→μ optics • Still linear A. Dobbs

13. Beam Loss and MICE Particle Rate Not linear at low beam loss... not to worry, believed to be caused by a mis-configured gate • +veπ→μ optics, “10V study” A. Dobbs

14. ...but what about Muons? • Use Time-of-Flight to perform Particle Identification • -veπ→μ optics A. Dobbs

15. Beam Loss and Muon Rate -veπ→μ optics • +veπ→μ optics • Still linear A. Dobbs

16. Muon Rate Numbers So, depending on MICE optics get a few 10’s of muons per 1ms spill A. Dobbs

17. Conclusion • The MICE Muon Beamline is functioning well in ISIS, and has been for sometime • Depending on MICE optics, the beamline delivers a few 10’s of muons per 1ms spill that can be used • Desired rate is several hundred “good” muons per 1ms spill • Would probably require beam loss levels that are intolerable to ISIS • Various solutions put forward: • Increased MICE target dip rate • Longer MICE data running to account for lower rates • ISIS beam bump at MICE target • Improved ISIS collimator system A. Dobbs

18. Appendix I: Run conditions A. Dobbs