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The GLD Concept

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Anti-solenoid Design of very forward detectors. Beam timing Readout scheme of VTX, etc. ... 8 mf 3T superconducting solenoid. Stored energy: 1.6 GJ. Excellent ... – PowerPoint PPT presentation

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Title: The GLD Concept


1
The GLD Concept
2
MDI Issues
  • Impact on Detector Design
  • L ? Background (back-scattered e- ,g, n) into
    VTX, TPC
  • Crossing angle ? Minimum veto angle for 2-photon
    process (important for SYSY search),
    back-scattered e- into VTX
  • Pair background ? VTX radius
  • Synchrotron radiation ? Beam pipe / VTX radius,
    background hits in trackers
  • Muons ? Detector hit occupancy
  • Neutrons from the extraction line ? Radiation
    damage on Si
  • DID ? TPC resolution
  • Anti-solenoid ? Design of very forward detectors
  • Beam timing ? Readout scheme of VTX, etc.
  • etc.
  • GLD detector concept study includes all these
    issues.
  • The baseline design should be compatible with the
    most severe case High Lumi option

3
Requirement from Physics
  • Impact parameter sb 5 ? 10/(pb sin3/2q ) mm
  • (c/b-tagging)
  • Momentum spt/pt2 5x10-5 /GeV
  • (e.g. H recoil mass reconstruction from
    Z?m pairs)
  • Jet energy sE/E 30/E1/2
  • (W/Z invariant mass reconstruction from
    jets)
  • Hermeticity q5 mrad
  • (for missing energy signatures, e.g.
    SUSY)
  • Sufficient timing resolution to separating events
    from different bunch-crossings
  • Must also be able to cope with high track
    densities due to high boost and/or final states
    with 6 jets, therefore require
  • High granularity
  • Good pattern recognition
  • Good two track resolution
  • General consensus Calorimetry drives ILC
    detector design

4
Calorimetry at the ILC
  • Much ILC physics depends on reconstructing
    invariant masses from jets in hadronic final
    states
  • Kinematic fits wont necessarily help Missing
    particles (e.g. n) Beamstrahlung, ISR
  • Aim for jet energy resolution GZ for typical
    jets
  • Jet energy resolution is the key to calorimetry
  • The best jet energy resolution is obtained by
    reconstructing momenta of individual particles
    avoiding double counting
  • Charged particles (60) by tracker
  • Photons (30) by ECAL
  • Neutral hadrons (10) by ECALHCAL
  • ? Particle Flow Analysis
  • The dominant contribution to jet energy
    resolution comes from confusion, not from
    single-particle resolution of CAL
  • Separation of particles by fine segmentation /
    large distance from the IP is important for CAL

5
Calorimetry Optimization for PFA
  • To avoid the confusion and get good jet energy
    resolution, separation of particles is important
    for CAL How?
  • Fine segmentation of CAL
  • High B field
  • Large distance from the IP ? Large Detector

Often quoted Figure of Merit
s CAL granularity RM Effective Moliere length
6
Calorimetry B or R?
  • B-field just spreads out energy deposits from
    charged particles in jet not separating neutral
    particles or collinear particles
  • Detector size is more important spreads out
    energy deposits from all particles
  • R is more important than B

GLD Concept Investigate detector parameter
space with large detector size (R) and slightly
lower magnetic field (B) and granularity
7
GLD Baseline Design
  • Large gaseous central tracker TPC
  • Large radius, medium/high granularity ECAL
    W-Scint.
  • Large radius, thick(6l), medium/high granularity
    HCAL Pb-Scint.
  • Forward ECAL down to 5mrad
  • Precision Si micro-vertex detector
  • Si inner/forwad/endcap trackers
  • Muon detector interleaved with iron structure
  • Moderate B-field 3T

VTX, IT not shown
8
Vertex detector
  • Role Heavy flavor tagging
  • Important for many physics analyses e.g. Higgs
    branching ratio measurement
  • Efficient flavor tagging requires excellent
    impact parameter resolution
  • Goal s 5 ? 10/(pb sin3/2q ) mm
  • Sensor technologies
  • Must cope with high background rate
  • Readout 20 times/ train, or
  • Fine pixel (20 times more pixels) option
    readout once/ train

9
Vertex detector
  • Main design consideration
  • Inner radius
  • Beam pipe radius Dense core of pair background
    should not hit the beam pipe
  • B-dependence not so large B-1/2
  • Large machine-option dependence
  • Back scattered e- from BCAL (Low-Z mask in front
    of BCAL should cover down to RltRVTX )
  • Layer thickness
  • As thin as possible to minimize multiple
    scattering
  • ? I.P. resolution / tracking efficiency for low
    p particles
  • GLD baseline design
  • Fine pixel CCD
  • Inner/outer radius 20(?) 50 mm
  • Angle coverage cosqlt0.9/0.95

10
Si trackers
  • Role Cover large gap between
  • TPC and VTX ? Si Inner Tracker (IT)
  • TPC and endcap ECAL ? Si Endcap Tracker (ET)
  • to get better
  • Track finding efficiency
  • Momentum resolution
  • Track-cluster maching in ECAL (PFA)
  • Design optimization
  • Number of layers and their position
  • Wafer thickness
  • Strip or pixel? for the very forward region

11
Main tracker TPC
  • Performance goal
  • spt/pt2 5x10-5 /GeV
  • combined with IT and VTX
  • Advantages of TPC
  • Large number of 3D sampling
  • Good pattern recognition
  • Identification of non-pointing tracks (V0 or kink
    particles) e.g. GMSB SUSY
  • Good 2-hit resolution
  • Minimal material
  • Particle ID using dE/dx

e e- ? ZH ? m m X
12
TPC
  • Baseline design
  • Inner radius 40 cm
  • Outer radius 200 cm
  • Half length 230 cm
  • Readout 200 radial rings
  • Open questions
  • Readout GEM or Micromegas?
  • Material budget of inner/outer wall and end plate
  • Background hit rate and its effect on spatial
    resolution due to positive ion buildup (occupancy
    is OK even with 105 hits in 50ms)

13
Tracking performance
  • GLD conceptual design achieves the goal of
    spt/pt2 5x10-5 /GeV

14
Calorimeter
  • Performance requirement
  • Goal for jet energy resolution is sE/E 30/E1/2
  • Then, what is the requirement for CAL?
  • The answer is not simple. We need a lot of
    simulation study of PFA

15
ECAL
  • Current baseline design
  • 33 layers of 3mm W 2mm Scinti. 1mm gap
    (readout elec.)
  • 28 X0, 1 l, RM18mm
  • Wavelength shifter fiber MPC (Multi-pixel
    Photon Counter, SiPM) readout
  • 4cmx4cm tile and 1cm-wide strips
  • Granularity has to be optimized by PFA simulation
    study
  • Calibration method for small segments is
    worrisome
  • Very fine segmentation with Si for first few X0
    is also discussed

MPC 400pixels
MPC 100pixels (10x10pixels)
16
HCAL
  • Current baseline design
  • 50 layers of 20mm Pb 5mm Scinti. 1mm gap
    (readout elec.) (Hardware compensation
    configuration)
  • 6 l
  • Wavelength shifter fiber MPC (Multi-pixel
    Photon Counter, SiPM) readout
  • 20cmx20cm tile and 1cm-wide strips
  • Granularity has to be optimized by PFA simulation
    study
  • Digital HCAL is also considered as an option
  • Open questions
  • Global shape Octagon, dodecagon, or hexadecagon?
  • How to extract cables?

Hamamatsu MPC (H100) spectrum Up to 40 photon
peak! is observed
17
FCAL/BCAL
  • BCAL
  • Locates just in front of final Q
  • Coverage down to 5mrad
  • W/Si or W/Diamond (No detailed design yet)
  • FCAL
  • Z2.3m
  • Also work as a mask protecting TPC from
    back-scattered photon from BCAL
  • W/Si (No detailed design yet)

18
Muon detector / Magnet
  • Muon detector
  • Possible technology Scintillator strip array
    read out with wavelength shifter fiber MPC
  • Number of layers, detector segmentation, etc.
    have to be studied
  • Magnet
  • 8 mf 3T superconducting solenoid
  • Stored energy 1.6 GJ
  • Excellent field uniformity for TPC

19
Cost Issues
  • Major cost consumers Solenoid, HCAL, ECAL
  • Solenoid
  • Cost0.523xE(MJ)0.662 PDG70M
  • HCAL
  • Volume230m3, Area (all layers)87Mcm2
  • Cost87M x cost/cm2
  • ECAL
  • Volume22m3, Area (all layers)37Mcm2
  • Cost37M x cost/cm2
  • Requirement for granularity from physics
    determines the CAL design and the cost
    Simulation study is urgent

20
Summary
  • GLD design study is being carried out both from
    accelerator point of view and from physics point
    of view
  • ILC detectors should be optimized for PFA
    performance, and large detectors are suitable for
    that
  • In GLD concept study, we investigate detector
    parameter space with large detector size and
    slightly lower B and CAL granularity
  • Baseline design of GLD has been shown, but
    current GLD baseline design is not really
    optimized. More simulation study, sub-detector
    RD effort, and new ideas are necessary
    ?The purpose of this workshop
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