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Collimation Studies for the Linear Collider

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... of TESLA collimation confirmed with MERLIN and BDSIM ... Confirm NLC and new ILC design performance with detailed simulations like STRUCT, BDSIM, MERLIN ... – PowerPoint PPT presentation

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Title: Collimation Studies for the Linear Collider


1
Collimation Studies for the Linear Collider
  • Frank Jackson
  • ASTeC Daresbury Laboratory (CCLRC)

2
Introduction
  • The design and performance of linear collider
    collimation
  • Introduction to beam delivery collimation in
    linear colliders
  • Purpose of collimation
  • Collimation requirements
  • Description of collimation system with comparison
    of TESLA and NLC
  • Collimation studies at ASTeC
  • Future direction

3
Purpose of Collimation
  • Future particle physics experiments need beam
    collimation
  • The halo of electron beams is a source of
    experimental background
  • Has been seen to limit experimental performance
    at Stanford Linear Accelerator
  • Collimation system also should provide energy
    collimation and machine protection

1 Beam Halo
Tracking Chamber Wires Hit ()
No Beam Halo
Collimator Aperture
4
Reason for Collimation
  • A very large halo will directly hit parts of the
    detector
  • Even a relatively small halo (10 times the beam
    size) can produce a fan of synchrotron radiation
    which may hit the detector
  • Synchrotron radiation fan is the main constraint
    on collimation depth sequence of spoiler
    apertures in BDS
  • Determining a realistic collimation depth is a
    complex, non-linear problem

5
NLC and TESLA Collimation Similarities
  • Both use betatron collimation section as the
    primary collimation instrument
  • Additional secondary collimators downstream
  • Betatron collimation
  • Dedicated section of beamline with optics purely
    designed for collimation
  • Illustration (TESLA)

Collimation depth
6
NLC and TESLA Collimation System Differences
  • Machine protection philosophy (dedicated optics
    vs consumable spoilers)
  • Energy collimation placement (upstream or
    downstream of betatron collimation)
  • Spoiler apertures and collimation depths
  • NLC betatron spoilers narrower than required
    collimation depth (apertures possibly determined
    by tracking)
  • TESLA spoilers set at collimation depth (linear
    semi-analytic design)

7
ASTeC Collimation Studies
  • Repeat existing international results on
    collimation
  • Set up tracking simulations MERLIN (N. Walker, A
    Wolski) and STRUCT (A. Drozhdin)
  • Measure and understand existing collimation
    designs
  • Previous studies were co-ordinated in a PAC2003
    contribution (A. Drozhdin et al)
  • NLC primary collimation efficiency 100
  • TESLA - fraction (0.01) of bunch (core halo)
    population escapes collimation depth
  • Qualitative behaviour of TESLA collimation
    confirmed with MERLIN and BDSIM

8
ASTeC Collimation Studies
  • NLC and TESLA halos at final doublet (Uniform
    phase space, 1 energy spread, MERLIN 2nd order
    transport)

NLC
TESLA
9
ASTeC Collimation Studies
  • NLC design apparently more efficient collimation
    system
  • Tighter collimation apertures (although less
    complete phase coverage)
  • Energy collimation scheme more effective
  • STRUCT provides more complete simulation (GEANT
    -based)
  • Secondary e/e- and ? production at
    spoilers/absorbers
  • Installed and running preliminary tracking
    simulations
  • Would benefit from benchmarking/comparison with
    other codes

10
Future Plans
  • Final collimation design will link closely to
    evolution of ILC BDS
  • Strawman BDS plan exists so far but no
    internationally agreed optics design
  • First attempts at ILC BDS put forward by SLAC for
    non-zero horizontal crossing angle, based on NLC
    design
  • First scheme may be to adopt NLC-type collimation
    system but this very dependent on many other BDS
    factors
  • Confirm NLC and new ILC design performance with
    detailed simulations like STRUCT, BDSIM, MERLIN
  • Investigate potential improvements
  • Muon and other secondary production should be
    included
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