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FNAL Feasibility Study on a Neutrino Source Based on a Muon Storage Ring

FNAL Feasibility Study on a Neutrino Source Based on a Muon Storage Ring. Norbert Holtkamp. Fardog Summary, Jan. 6th ‘00. Results from recent technical discussions some nice technical solutions some results with impact on the physics study Status of the study Timing. The Task.

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FNAL Feasibility Study on a Neutrino Source Based on a Muon Storage Ring

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  1. FNAL Feasibility Study on a Neutrino Source Based on a Muon Storage Ring Norbert Holtkamp Fardog Summary, Jan. 6th ‘00 • Results from recent technical discussions • some nice technical solutions • some results with impact on the physics study • Status of the study • Timing

  2. The Task • A design concept for a muon storage ring and associated support facilities that could, with reasonable assurance, meet performance goals required to support a compelling neutrino based research program. • 2.Identification of the likely cost drivers within such a facility. • 3.Identification of an R&D program that would be required to address key areas of technological uncertainty and cost/performance optimization within this design, and that would, upon successful completion, allow one to move with confidence into the conceptual design stage of such a facility. • 4.Identification of any specific environmental, safety, and health issues that will require our attention.

  3. Choice has been made ! • Basic Calculation • 1/3 of the muons decay in the straight section (38 %) • 10 protons for 1 m into the storage ring (>10; >20-50) • 2x107 sec • 2x1013 proton on target per pulse @ 16 GeV and 15 Hz • 3x1013 proton because of carbon target • 2x1012m per pulse to be accelerated and injected into the ring • cooling channel not successfully simulated < 2x1012 • longer bunch in the proton driver and on target (1 nsec  3) • helps • ring tilt angle is 13deg ( 22 %) instead of 35 deg (57 %) • ring with these params. Is not a cost driver at all

  4. The Neutrino Source • Approach: • go more conventional where ever possible • Oak Ridge, FHML, Brookhaven  the target • most people bought the solid target • Jefferson Lab / Cornell  sc rf and re-circulating linacs • biggest disconnect right now • LBNL , DUBNA  induction linacs (talk tomorrow) • goes much better than expected but not cheap • IHEP Protvino sc solenoid channels • so far very good job • specific design and engineering (cooling channel, target collection, beam manipulation, beam tracking and simulation)  Muon Collider group (12 people @FNAL) + the collaboration • ( thank Andy for the enormous support) • general engineering (large scale rf systems, sc magnets, sc solenoid channels, ps, vacuum, beam lines, tunnel, water)(20 FTE for 6 month) • very good support from FESS and TD • not easy to convince somebody in BD that anything else than TEVATRON is useful at all.

  5. The Neutrino Source • First experiment based on an intense muon source -> does it have to be 50 GeV ?? • 10 GeV and 50 kT or more magnetized water detector: Goal: Balance detector cost with Accelerator: E*kT*I=const. • Start with 2x1019/year (Sessler, Geer) and still good physics

  6. Neutrino Source Study @ FERMI • Application of a “Generic Neutrino Source” to specific site • Base the study on specific set of Parameters • 6 month period of time to define the R&D program and develop a layout to investigate the scope of such a complex Generic Layout collaboration paper “deviate wherever necessary or useful” Physics Study in parallel H. Schellmann / S. Geer

  7. Footprint for a 50 GeV Neutrino Source • Infrastructure is very close together ...

  8. R & D Issues for the Proton Driver Design Study • R & D groups: • Goal: • 4 x 0.75x 10-13 = 3x 10-13 @ 15 Hz • 8 GeV versus 16 GeV versus higher energies ? • Very hard to get people going on this: Only Chuck A. • Will probably not appear in the report in detail • Why? • Power bill is dominated acceleration • at low Frequ. Tfill is large compared to T pulse • most of the time power source is on for filling • -> higher rep rate less efficient; peak current is limit too. • Go to higher energies (more acceleration): Higher Proton beam energy and smaller rep rate is more efficient way to produce beam power

  9. What changes compared to MC • The target • Ptarget is still of the order of 1.5 (graphite) with upgrade possibility to 4 MW (probab. Liquid) • RF after target only gives increase in Polarization from 28% to 40% -> it is not worth it !! A. Blondel from CERN • Target dissipation is only 30 kW or so -> radiation cooled • Radiation damage is a major constraint for sc coil. 0.5 - 1 year is most probable lifetime so far • 20 T can only be achieved with sc +nc coil. • Disagreement between people on the fatigue limits calculated and the actually NuMI test. 30 - 60 MHz rf ~ 5 MV/m

  10. Target for a Neutrino Factory • 1 - 2 MW target • Reduce power in the target -> low Z • Solid Target: loose x 1.5 in yield -> more protons -> ok at this intensity • Magnet radius is too small, especially with Copper inside

  11. Induction Linacs and Long Solenoidal Channels 50 m drift before f rotation For carbon target: 0.10 m/p between 225 - 240 MeV 0.13 m/p between 220 - 250 MeV 0.18 m/p between 200 - 270 MeV • Trade off: • Energy Spread after rotation drift channel length[loss] • Particle capturelength(voltage) in induction linac[loss] •  simplest solution offers comparable yield

  12. Induction Linac Layout • Strong Effort at LBL for DAHRT • A little bit of expertise at Fermi • higher field 2-3 T and smaller cores may be better solution • saturation in the cores is under control • switching is the main problem Small effort at FNAL: “old” expert from DUBNA no working in TD. Mainly on solenoid channel design

  13. LBNL Status • Induction Cell • basically ok. Trade off between: operational and investment cost • Pulser system: • still not so clear: 4 pulse per burst… • asymmetric voltage

  14. The Heart of the Cooling Channel for a Neutrino Factory • IIT, BNL, LBNL, FNAL: go through an engineering design faster • Goal: Do all the cooling with one set of hardware RF may be, solenoids no • Analytical (Courant Snyder type description of the motion in Solenoidal channel) LBL Bz ~ 5 T max Eacc ~ 15 MV/m @ 200 MHz

  15. The Cooling Channel • +/- 3.5 T up to 5T or more Lattice with 15 MV/m 175 MHz rf • period gets shorter and shorter Reduces to about 100-140 m of cooling channel

  16. 200 MHz Cavity + Power Source • Engineering Layout required for the study • Want to build and test it, once study is done 1/8th of the full accelerating cell ~ 0.65 m Enhance the E Field on Axis by using a grid Goal: 15 MV/m nc cavities ~ 0.65 m

  17. Acceleration based on RLA • Why not nc? • Peak power limited already • in normal conducting cavity: too much power required to build up the gradient • gradient is not a free parameter for optimization: • muon decay +longitudinal acceptance • SC structures at 200 MHz (100 MHz) and 10 MV/m (7,5 MV/m real estate) • almost no power to build up gradient --> beam • loaded Q’s are similar to nc structures ->fill time short but coupler ? -> comparatively efficient ! • 4 x 30 bunches per RLA, 2.5x1012 total • Plinac ~ 6 MW, PRLA1 ~ 2 MW, PRLA2 ~ 12 MW • ~20 MW power for RF acceleration at ~25 % overall efficiency (AC  RF) • Problem is the required peak power not average power !

  18. Optimization of the Storage Ring • The cheapest way to produce muons in the straight section is to make them as long as possible ! Nr of m decaying in straight section h = Nr of m injected 1 1 h = = L=length of straight 2 (1+p r /L) 2 (1+0.2) B / Tesla • Problem with dynamic aperture due to short Magnets and large aperture (10x15 cm) -> not fixed yet

  19. The SC Large Bore Magnets • Low field quality helps reduce price although large aperture • main heat load due to m-decay, probably not optimum • 1 cm tungsten liner instead of 3 cm

  20. Large Bore Magnets • Similar magnets for the RLA Arcs with less tungsten shielding • Bigger magnets in the Beam Spreaders of the RLA arcs + combined function • Energy Acceptance of the Arcs ?????? Storage Ring Arc Cell

  21. The Storage Ring Location@ FNAL

  22. Storage Ring Layout • Site layout for the Storage Ring and the Arcs • Experimental beam lines and halls • Cryo space requirement

  23. Goal & Schedule • 6 Month study:  “10 pages of paper per subsystem+ 1 schedule + 1 cost” • Internal Review Feb. 15th and 16th for the Accelerator part, Feb. 17th and 18th for Geer/Shellman to align the different contributions • Documents in by beg. of march • Report out by March 30th if that’s acceptable • Most risky • induction linac (no, only expensive ->R&D) • cooling channel design and performance • what is the minimum emittance achievable • it is still the most unreliable item • acceleration: ( largest cost driver) • Jefferson Lab  Cornell CERN  SLAC  Fermi • after Feb. 15th & 16th have working meeting with these groups to go through: Cryo, cavities, couplers and power sources • not sop clear how to organize it

  24. Cost • Hot Topic: Preliminary result.

  25. Questions • What comes after the study ? • Review the results • Does the lab want to do this ? • If done or obvious: Define the R & D program • remember: 10 different subsystem and all need strong R&D program … a lot of people, time and money. • Develop efficient and cost effective accelerating systems at low frequency • Prepare a site where this experimental program can be pursued • leading role for Muon Cooling Directors office

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