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WG2 Proton FFAG Summary

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Three free-edge corner foil. High power electron collector ... More compressors to solve foil heating problem. E.g. 3 rings of 1/3 circumference of FFAG ... – PowerPoint PPT presentation

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Title: WG2 Proton FFAG Summary


1
WG2 (Proton FFAG) Summary
  • G.H. Rees

2
Proton Driver Working Group
  • Participants
  • M. Yashimoto, S. Ohnuma, C.R. Prior, G.H. Rees,
    A.G. Ruggiero
  • Topics
  • FFAG or RCS proton driver for a Neutrino Factory
  • 1 GeV, 10 MW Proton Driver
  • 1 kHz H? Linac 1 kHz FFAG, or
  • 50 Hz Proton Linac

3
Neutrino Factory Driver
RCS Designs 4 MW, 1 ns rms bunches
  • Solutions found for
  • H? injection at 180 MeV
  • Collimation
  • Bunch Compression to 1 ns rms

4
FFAG
  • Short straights make difficulties for
  • H? injection
  • Collimation
  • Spallation Neutron Sources favoured
  • Linac/compressor ring over FFAG, or
  • RCS over FFAG (old, out-of fashion)

5
Possible 50 Hz Neutrino Factory Driver
  • 180 MeV H? Linac ? 3 GeV Booster (?2)
  • ? 8 GeV FFAG (?1)
  • (An 8 GeV FFAG replaces two 8 GeV RCS)
  • If practical, would have some advantages
  • More rugged
  • Able to hold bunches until needed
  • But
  • May need separate compressor ring.

6
10 MW Proton Driver
1 GeV, 1 kHz protons
  • Comparison
  • Capital cost 20 year operating cost
  • Total power levels involved are important, and
  • Number of operating staff

7
Comparison of R/T Linacs
  • Proton Linac has advantage
  • Structure power down by 1/3
  • May use fewer, higher peak power klystrons
  • Requires no chopper
  • Chopper for H? linac is beyond state of art
  • So, proton linac has head start over FFAG

8
10 MW, 1 kHz FFAG
  • Will foil survive?
  • Compare with other designs, for example
  • 2.5 MW, 50 Hz (20 ms cooling time)
  • ?T1000?C, T 1000 to 2000?C
  • (State of art injection system with H? through
    foil and on average 2 later traversals/proton)

9
H? Injection
  • Needs to be studied very carefully
  • State of art injection required
  • Programmed H and V bumps
  • Three free-edge corner foil
  • High power electron collector
  • Removal of unstripped beam from ring (Hº)
  • To modify his design, A. Ruggiero has begun a
    study of insertions

10
H? Injection (continued)
  • May be forced to
  • Or even
  • More compressors to solve foil heating problem
  • E.g. 3 rings of 1/3 circumference of FFAG

11
FFAG Collimation/Protection
  • Acceptable loss over most of ring 500 Watts
  • Acceptable loss in dedicated collimators lt 5 kW
  • (5 parts in 105, 5 parts in 104)
  • Studies at SNS, ORNL suggest
  • ?Qlt0.2 for 1 part in 104 loss
  • Ruggiero design has ?Qlt0.35 at 200 MeV
  • So injection energy 200?400 MeV?

12
Collimation
  • No problem in designing collimators for the
    suggested compressor rings
  • Insertions may be needed for the FFAG
  • Note (also for an RCS)
  • Bump magnets needed in the collimation straight
    insertions
  • Vertical and horizontal bumpers needed
  • Halo surviving to top energy may get lost on
    extraction elements
  • Note for FFAG
  • Beam lost longitudinally may survive at low
    energy
  • ? kick out before next pulse?

13
Collimation
  • Resonance crossing may be a problem
  • Basic FFAG has high periodicity
  • But if insertions are introduced, periodicity is
    reduced
  • Major effect probably space charge induced
    coupling at lower energies
  • Control of tunes likely to be needed over
    acceleration
  • Radiation hard magnets in collimation regions

14
Other Thoughts
  • Advisable to guard against e-p instability
  • Coating of vacuum chamber
  • Effect of shape of vacuum chamber
  • Instabilities may be an issue at lower energies
  • Effect of stray fields of injection/extraction
    septa and rf cavities

15
Summary
  • The possible use of an FFAG in a Neutrino Factory
    Proton Driver has been outlined
  • For a 1 GeV, 10 MW proton driver, a detailed cost
    comparison is suggested between the two scenarios
    discussed
  • Note In a 25 MW, 1 GeV proton driver study, the
    following were considered
  • 1 GeV proton linac, 50 Hz
  • Three 8 MW cw cyclotrons
  • Two 12.5 MW separated orbit cyclotrons
  • It was found that a) was the cheapest option.
  • The FFAG option was not considered.
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