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Epicyclic Helical Channel for Parametricresonance Ionization Cooling PIC

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Be wedge included in the walls replaces grids used with HPRF ... Work Plan. Numerical studies of orbital motion in epicyclic (double-periodic) channel ... – PowerPoint PPT presentation

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Title: Epicyclic Helical Channel for Parametricresonance Ionization Cooling PIC


1
Epicyclic Helical Channel for Parametric-resonanc
e Ionization Cooling (PIC)
  • V.S. Morozov
  • Old Dominion University
  • V. Ivanov, R.P. Johnson, M. Neubauer
  • Muons, Inc.
  • A. Afanasev
  • Hampton University and Muons, Inc.
  • A. S. Bogacz, Y.S. Derbenev
  • Thomas Jefferson National Accelerator Facility
  • K. Yonehara
  • Fermi National Accelerator Laboratory

2
PIC Concept
  • Parametric resonance induced in muon cooling
    channel
  • Muon beam naturally focused with period of free
    oscillations
  • Wedge-shaped absorber plates combined with
    energy-restoring RF cavities placed at focal
    points (assuming aberrations corrected)
  • Ionization cooling maintains constant angular
    spread
  • Parametric resonance causes strong beam size
    reduction
  • Emittance exchange at wedge absorbers produces
    longitudinal cooling
  • Resulting equilibrium transverse emittances are
    an order of magnitude smaller than in
    conventional ionization cooling

3
PIC Schematic
  • Equilibrium angular spread and beam size at
    absorber
  • Equilibrium emittance
  • (a factor of
    improvement)

4
PIC Requirements
  • Varying dispersion
  • small at absorbers to minimize energy straggling
  • non-zero at absorbers for emittance exchange
  • large between focal points for compensating
    chromatic and spherical aberrations
  • Correlated optics
  • normal-mode oscillations periods must be
    low-integer multiples of dispersion magnitude
    oscillation period ?1,2 / ?D 1 or 2
  • Required features can be produced by epicyclic
    magnetic field configuration
  • solenoid with two superimposed different-period
    transverse helical fields
  • uniform smoothly-varying fringe-field-free
    configuration

5
Simplified PIC Model
  • Two transverse helical fields with wave numbers
    k1 and k2
  • Equation of motion
  • Cyclotron wave number
  • Analytic solution under approximation kc const
    (pz const)

6
Oscillating Dispersion
  • Dispersion function containing two oscillating
    terms
  • Condition for dispersion to periodically return
    to zero
  • k1? k2? kc/2 ? k gives B1? 9B2 and elliptic
    orbit
  • Dispersion function

7
Oscillating Dispersion (Cont.)
p?p?p
absorbers
aberration correction
8
EPIC Based on HCC
  • ? ? pT /pz 1 gives more complicated picture
  • Since B2 ltlt B1 , consider secondary helix
    perturbation
  • Start with single-periodic Helical Cooling
    Channel (HCC)
  • exact analytic solution
  • well-studied in simulations
  • orbit stability conditions

9
HCC Stability Region Normal-Mode Tunes
  • In usual HCC sgn(k) sgn(kc), ? gt 0
  • In EPIC channel sgn(k) ?sgn(kc), ? lt 0

10
Adiabatic Turn On of Secondary Helix
11
Effective Force Approach
  • Introduce effective friction force
  • total energy conserved while phase volume is not
  • analogous to cooling
  • all trajectories converge towards periodic orbit
  • aids in finding periodic orbit when analytic
    solution is not available

12
EPIC Dispersion in Realistic Fields
G4BeamLine p 250 12.5 MeV/c low ? for primary
helix
Matlab p 100 1 MeV/c ? 1 for primary helix
13
Possible Technical Implementations
  • Solenoid with direct superposition of required
    helical harmonics
  • Adopt procedure developed for HCC by Kashikhin et
    al.
  • circular current loops centered on elliptical
    helix (different from periodic orbit)

14
Incorporating RF in 2-period HS
  • Hydrogen-pressurized RF cavity
  • Be wedge included in the walls replaces grids
    used with HPRF
  • many of required technical solutions already
    exist (using ceramic ring to adjust frequency,
    small-diameter power feed through)
  • or Tapered no-RF cooling blocks with RF sections
    in between
  • Transverse-longitudinal coupling is minimal

15
Recent Progress
  • Found magnetic field configuration giving
    required dispersion
  • uniform
  • smoothly-varying
  • fringe-field free
  • Showed preliminary demonstration of needed
    features
  • Developed technique to identify periodic orbit
  • straightforward to find normal-mode tunes
    numerically using single-period orbital transfer
    matrix
  • Came up with ideas for technical implementation
  • Have ideas how to incorporate RF
  • Started preliminary G4BeamLine simulations

16
Work Plan
  • Numerical studies of orbital motion in epicyclic
    (double-periodic) channel
  • Use developed tools to determine stability region
    around periodic orbit
  • Determine characteristic parameters such as
    normal-mode tunes
  • Learn to control parameters of motion with
    quadrupole and higher-order magnetic fields
    components
  • Identify configuration and strengths of sextupole
    and octupole field components for aberration
    corrections
  • Demonstrate in full-scale G4BeamLine simulations
  • compensation of chromatic and spherical
    aberrations
  • cooling and emittance exchange with wedge
    absorbers
  • Explore possible technical solutions
  • Study implementation of RF cavities as part of
    PIC channel design taking into account scattering
    in pressurizing gas if needed
  • Investigate space-charge limitations

Muon Collider Design Workshop BNL, December 1-3,
2009
16
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