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First Thoughts on IDS

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1.5 GeV 1 Dog-bone (chic) 2 (5-10 & 10-20 GeV) 0.9 GeV 2 Dog-bones (chic) 1 (12.5 to 25 GeV) ... 2 Dog-bones (no chic) None, or (2.25-7 & 7-25 GeV) 1 (25 to 50 GeV) ... – PowerPoint PPT presentation

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Title: First Thoughts on IDS


1
First Thoughts on IDS
  • G H Rees, RAL

2
Topics
  • Two-way, µ injection chicane for the dog-bone
    RLA.
  • Injection energy efficiency for a first
    dog-bone RLA.
  • 3. Injection and extraction efficiency for an
    FFAG.

3
Evolution of NF Muon Acceleration
  • Linac Energy RLA stages
    FFAG stages
  • 3.0 GeV 2 Racetracks
    None
  • (3-11 11-50 GeV)
  • 1.5 GeV 1 Dog-bone (chicane) 2
    (5-10 10-20 GeV)
  • 0.9 GeV 2 Dog-bones (chicane) 1
    (12.5 to 25 GeV)
  • Q. How does 2-way chicane allow such a low
    injection energy?

4
Two-way, µ injection chicane
  • .

µ D
l
µ µ
?1 5?/8
?
1.5 GeV 0.9 GeV
µ
5
Approximate Data for a Two-way Chicane
  • Dipoles 2/3 m, sepns 2 m, ß 4 m, en 30
    mm, ? 7
  • D (µ deflection shown) 2 tan ? 2 (1- cos
    ?)/3?
  • 2 tan ?1 (1- cos ?1)/?1 1.8vße 2?(tan ?
    tan ?1 ?/3) l
  • Central, two-way dipole (B) cannot be a septum
    magnet.
  • Solutions then require D gt 4 m, ? gt 60 and B gt
    11 T.
  • Practical solutions dont seem possible for the 6
    m chicane, nor
  • for a longer chicane, with an added septum and x
    2 µ cooling.

6
Consequences of not using a Chicane
  • 1. Injection of µ into upstream end of the
    RLA straight
  • 2. A higher energy injector is required for
    the first RLA
  • 3. There is a half-turn gain of acceleration
    in the RLA
  • 4. Different µ injection and µ transfer
    lines required
  • Reassessment of pros cons of dog-bones
    racetracks
  • 6. There is no longer a base line NF design

7
Pros cons of dog-bones racetracks
  • 5-pass Dog-bone RLA 4½-turn
    Racetrack RLA
  • 2 x 2 droplets (4 x 360-420) 2 x 4 arcs
    (8 x 180)
  • 1 long linac, energy E 2
    short linacs, energy E/2
  • total energy gain 5 E total
    energy gain 4.5 E
  • sepn 2E in arcs/spreaders sepn E
    in arcs/spreaders
  • same µ beam focusing
    different µ beam focusing
  • crossing of droplet orbits no
    crossing of orbits
  • On balance, the dog-bone RLA is still the
    favoured choice

8
Energy Range of Revised Dog-bone RLAs
  • An earlier, 3½ pass dog-bone RLA had energies 1½
    to 5 GeV.
  • The first, full energy pass through linac was
    from 2 to 3 GeV.
  • So, assume a first full energy linac pass from 2
    to 3 GeV
  • and four further linac passes of 1 GeV to reach 7
    GeV.
  • There are then many options, eg, RLA RLA, 2RLA
    FFAG
  • A five pass, RLA with 3.6 GeV per pass could
    reach 25 GeV.
  • Fast ejection (as in racetrack) prob. not needed
    for dog-bone.
  • Q. If 50 GeV needs 2 RLAs, why does 25 GeV need 3
    accels?

9
Injection Energy for the First RLA
  • Choice of the energy depends on the µ injection
    efficiency.
  • Carol Johnstone required a racetrack at 3 GeV for
    en 15 mm.
  • Chicane design assumes dog-bone at 0.9 GeV for en
    30 mm.
  • No-chicane, dog-bone, ?f-s req. is 2.0 GeV for
    en 30 mm.
  • No-chicane, dog-bone, efficient injection req.
    may be gt 2 GeV
  • Spreader injection involves 3 (5) orbits for
    dogbone (racetrack).
  • Spreader injection study is needed to decide
    injection energy.

10
Further Evolution of µ Acceleration?
  • Linac Energy RLA stages
    FFAG stages
  • 3.0 GeV 2 Racetrack
    None
  • (3-11 11-50 GeV)
  • 1.5 GeV 1 Dog-bone (chic) 2
    (5-10 10-20 GeV)
  • 0.9 GeV 2 Dog-bones (chic) 1
    (12.5 to 25 GeV)
  • 2.25 GeV? 2 Dog-bones (no chic)
    None, or
  • (2.25-7 7-25 GeV)
    1 (25 to 50 GeV)

11
Injection Extraction for FFAGs
  • Kicker-septum systems pulsed power scales
    approx. as (en)2.
  • Kickers only pulsed power is F (en , w (cryostat
    dimension))
  • and the extraction is more
    difficult than injection.
  • At 25 GeV a 1.46 m, 1 T septum unit bends the
    beam by 1
  • and displaces it lt w
    (septum, shield vac. wall).
  • So, there is no advantage in
    such a septum unit.
  • Decay ring 20 GeV, ?k 6.47 mr, 24 m kicker,
    44 m straights,
  • 7, shorted, 3m, 10 O delay
    line, push pull K with
  • 14 x (50 kV PFN, 5 kA pulsers
    10 O feeders)/ring
  • FFAG ring 25 GeV, ?k 30 mr, 1.2 m kicker, B
    field x100

12
FFAG Injection and Extraction.
  • Pulsed powers for kickers 20 x that of state of
    the art kickers.
  • Deflecting fields in kickers 40 x that of state
    of the art kickers.
  • Induction linac modulators are able to produce
    the pulse power,
  • when driving cavities with toroidal B fields,
    longitudinal E fields.
  • Different drive arrangements allow different
    impedance levels.
  • Short, transverse deflection kickers do not have
    many options
  • push-pull, 1-turn windings, each with a low Z,
    matched feeder.
  • Difficult to transform from the low Z and the
    very high current.
  • To see if such short kickers are feasible, R and
    D is needed
  • in collaboration with an experienced, induction
    linac group.

13
Injection Extraction Efficiency
  • Most, existing fast injection and extraction
    systems use
  • zero dispersion straight sections, linear
    focusing regions,
  • low beam emittances and a low beam momentum
    spread.
  • None of these conditions apply to the 12.5-25 GeV
    FFAG.
  • Linear, n-sc, FFAGs now consider adding sextupole
    comps.
  • Special wide aperture magnets are needed for
    inj(ej) channels.
  • Study needed of effect on in(out)put matching and
    efficiencies.
  • Racetrack RLAs needed fast extraction, but not
    fast injection.
  • Hopefully, the dog-bone RLAs will not need any
    fast system.

14
Summary
  • A 2-way, 0.9 GeV injection chicane may not be
    feasible, so
  • injection at 2 GeV may be needed for a
    first dog-bone RLA
  • A possible, µ acceleration scenario could then
    consist of
  • 5-pass, dog-bone RLAs at 2.25 to 7 GeV and 7
    to 25 GeV
  • This would defer choice between a dog-bone and an
    FFAG
  • accelerator to the higher energy range from
    25 to 50 GeV
  • A 3 orbit, reverse beam spreader design is needed
    for dog-bone RLAs, and estimates made of the
    injection efficiencies
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