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Breaking the mold : Neutrinos & the accelerators of tomorrow

2/20. Breaking the mold : Neutrinos & the accelerators of tomorrow. V. Blackmore. Contents. Neutrino physics today A route to new accelerators The long & winding road. Neutrino Oscillations. where. The “relationship” between neutrino flavour and mass.

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Breaking the mold : Neutrinos & the accelerators of tomorrow

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  1. 2/20 Breaking the mold: Neutrinos & the accelerators of tomorrow V. Blackmore

  2. Contents Neutrino physics today A route to new accelerators The long & winding road

  3. Neutrino Oscillations where The “relationship” between neutrino flavour and mass. Non-zero  can measure , CP violating phase New

  4. Facility Checklist or

  5. A New Facility? Current Experimental Reach Precision P. Huber et. al., JHEP 11 044 (2009) P. Coloma, et. al., arXiv:1203:5651 Yes please!

  6. Muon beams to the rescue

  7. The Muon Advantage Source Oscillation Detection CC CC Superbeam CC CC CC CC Muon Beam CC CC

  8. The Muon Advantage Source Oscillation Detection CC CC Superbeam CC CC CC CC Muon Beam CC CC

  9. nuSTORM: A Neutrino Factory “Test Facility” Test LSND/ MiniBooNE anomaly 150 m Measure , cross-sections 100kW Neutrino Factory Test Facility

  10. Muons are challenging Production Acceleration Control

  11. Neutrino Factory Low Luminosity Neutrino Factory No cooling, Low Energy Neutrino Factory With cooling, “IDS” Neutrino Factory With cooling,

  12. Luminosity “Achieving a high luminosity is simple, all one has to do is make high population bunches of low emittance collide at high frequency at locations where the beam optics provides as low values of the amplitude functions as possible” – PDG (paraphrased)

  13. Liouville’s Theorem 2nd Moments conserved quantity General physics theorem: “The volume of phase space occupied by a system of particles is constant*” *When considering conservative forces

  14. Amplitude, Emittance & Amplitude Low luminosity Want Improved luminosity

  15. NF Requirements To first approximation: Acceptedbeam: Low luminosity Want Improved luminosity

  16. Initial* emittance estimates Post-production muons Low Energy NF (muon collider) We must violate Lioville’s Theorem! *Approximate size estimations! Dramatic license application in progress...

  17. Violating Liouville’s Theorem: A “How To” Guide Standard emittance reduction techniques Ionisation cooling

  18. Proven Techniques p Measure Synchrotron/Radiative Cooling Stochastic Cooling Storage Ring Dipole e Kick p Synchrotron Radiation Pros: Fast cooling Cons: Works best for light particles, too heavy! Pros: Works well for heavy particles Cons: Takes time, too short-lived!

  19. Ionisation Cooling RF Cooled beam : Small focus at absorber : Liquid hydrogen Absorber Restores only longitudinal momentum , phase space reduced Reduces all momentum components 0000000000000000 Cooling Heating (Mult. Scat)

  20. MICE The Muon Ionisation Cooling Experiment

  21. The Cooling Channel RF 4T Solenoid field, scintillating fibre tracker Measures components: Measure Cool Absorber Reaccelerates , restoring lost energy and Spectrometer Solenoid Measure Liquid hydrogen or solid Lithium Hydride. Reduces momentum vector

  22. The Beam Line 800 MeV Protons x Target Quadrupole Triplet Upstream Downstream Dipole #1 Dipole #2 BPM TOF0 TOF1 Cooling Channel Decay Solenoid Quadrupole Triplet Quadrupole Triplet Ckov

  23. The Beam Line 800 MeV Protons x Target Quadrupole Triplet Upstream Downstream Dipole #1 Dipole #2 BPM TOF0 TOF1 Cooling Channel Decay Solenoid Quadrupole Triplet Quadrupole Triplet Ckov

  24. Busy MICE…

  25. Magnets

  26. Data (-, +) Reconstructed Sim. (-, +) MICE Step I (Preliminary Plots!)

  27. Great Expectations • Input derived from measured beams • Muon selection based on momentum only: • Gaussian with • Beam is matched and cools well 17% (Preliminary Plots!)

  28. Intense Proton Source Test Facility, STORM Neutrino Factory But wait! 125 GeV Higgs Factory 4 TeV -Collider The non sumusinsanes, vere applications Dictated by LHC discoveries

  29. Size Matters (?) Source: Fermilab & MAP

  30. Neutrinos to Muon Colliders Neutrino Factory Muon Collider S. Geer, Annu. Rev. Nucl. Part. Sci. 2009. 59:347–65

  31. The Future of Ionisation Cooling Muon Collider goal NF cooling (Reverse Emittance Exchange) (Parametric-Resonance Ionisation Cooling) Figure from [2]

  32. The Future of Ionisation Cooling RFOFO Ring Cooler1 Helical Cooling Channel2 Guggenheim Cooling Channel3 Parametric Resonance Ionisation Cooling4

  33. Summary • is large, possible to measure CP violation and absolute scale of mass hierarchy • Require a precision machine • Neutrino Factory is still the best option • Technology well underway • MICE will demonstrate ionisation cooling • Required for Low Energy Neutrino Factory • Will be one step closer to a Muon Collider • Until then, keep an eye on the STORM!

  34. Backup Misc. figure references

  35. Misc. Figure References • Ionisation cooling ring for muons, R. Palmer et. al., PR-STAB 8, 061003, 2005 • A helical cooling channel system for muon colliders, K. Yoneharaet. al., FERMILAB-CONF-10-108-APC • Recent progress on the 6D cooling simulations in the Guggenheim channel, P. Snopoket. al., Int. J. M. Phys A, 24, pp987 – 998, 2009 • Progress towards Parametric-Resonance Ionisation Cooling in the twin helix channel, J. A. Maloney et. al., NuFACT12

  36. Conventional Emittance Measurements Dense grid (a) Measure beam size along beam line (c) Use “Pepper pot” Beamlet Beam Scintillating screen Beam Beamlet Beam Beamlet (b) Measure beam size at fixed position and increasing quadrupole strength Deduce emittance from beam size measurements Deduce from beam size & divergence

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