Introduction to Large/Huge Detector
study
10. Nov. 2004@Kick-off meeting in
7th ACFA LCWS in TaipeiY. Sugimoto
KEK
Organization/Schedule None of SiD, Middle (TESLA), Large/Huge detector study group i
s a “Collaboration” in HEP sense. You can contribute to more than one study group. The tails of 3 gaussian peaks overlap with each other.
The study groups should be international (World-Wide Study) Actually, inter-regional detector R&D collaborations (Horizontal c
ollaborations, such as LC-TPC, CALICE, SiLC) can contribute to two or three study groups
Milestone: Detector cost estimation by WWS costing panel at the end of 2005 We hope the concept will survive until CDR (2007?) and TDR (2009?) In a shorter range, we should present study results at LCWS2005 in Ma
r. at SLAC and Snowmass workshop in Aug.2005.
Large/Huge detector concept GLC detector as a starting point Optimization mainly for PFA
Larger main tracker outer radius/ECAL inner radius Larger Z position of EC CAL inner surface Longer tracker/solenoid
Keep B field 3T (Stored EVTX(beam b.g.)/TPC(duffusion) resolution)
Re-consider the optimum sub-detector technologies based on the recent progresses
GLC Detector: Baseline detector (Minimum performance) Large/Huge Detector: State-of-art detector (Performance to get maximum physics output), backed up with simulation studies and detector R&D (anticipated in near future)
Simulation study
Select minimum set of physics processes without duplication of final-state topology for the detector benchmark
For the moment, the topology up to 4-fermion final state with and without missing energy should be considered
There are two types of detector performances: Process-dependent: Detector performance can be determined only when
the physics process is specified. It affects the physics output, of course. c- and b- tagging efficiency Jet energy resolution
Process-independent: Detector performance is rather independent of process, but affects physics output Pt resolution Particle ID capability (K/, ) Minimum veto angle
Anything else?
Simulation study
Other basic simulations Detector full simulation specific to each sub-detector or co
mbination of sub-detectors, but rather independent of physics processes. For example; Tracking efficiency of vertex detector with beam backgroun
d Effect of tail catcher on the neutral hadron E resolution Effect of two-photon background on the TPC resolution Pt resolution v.s. number of sampling
The results of these simulations become inputs to or bases of the benchmark simulations
Detector R&D
ECAL HCAL Main tracker Solenoid magnet Si inner tracker Vertex detector Si pair monitor
Muon system Si outer tracker Si endcap tracker Si forward disks Forward calorimeter Beam calorimeter PID DAQ system/Trigger(?)
Summary
Too many study issues to be summarized as an introduction
A lot of jobs including clarification of physics requirements, detector full/quick simulation, and detector R&D are awaiting us
Defining the jobs may be the first job to be done
Backup slides
Detector components
EM Calorimeter Small Rm
eff W radiator Make gaps as small as possible
Small segmentation : seg < Rmeff
Hadron Calorimeter Options
Absorber: Pb or Fe ? Sensor: Scintillator or GEM ? Digital or not digital ? Tail catcher behind solenoid needed?
Choice of calorimeter options depends on the results of future detector R&D and detector simulation
Detector components
Main tracker TPC is a natural solution for the Large tracker
Positive ion feedback (2- background) ? Study of gas with small diffusion
Small-cell jet chamber as an option (End plate would be much thicker than TPC)
Solenoid magnet Field uniformity in a large tracking volume
Is 2mm limit really needed?
mmdzBz
Brz2max
0 (TESLA TDR)
Detector components Muon system
No serious study for GLD so far Design of muon system is indispensable for the solenoid/iron-yoke desig
n, which takes large fraction of the total cost How many layers? How thick? Which detector option?
Si inner/outer(?) tracker Time stamping capability (separatio
n of bunches) High resolution Si strip det. improves momentum resolution Z-measurement needed?
Si endcap tracker Improves momentum resolution in the end-cap region where main
tracker coverage is limited
pt/pt2
TPC only 1.2e-4
TPC+VTX 4.5e-5
TPC+VTX+SIT 2.9e-5
SIT: =7m, 3 layersVTX: =3m, 5 layers
Detector components Si forward disks / Forward Calorimeter
Tracking down to cos=0.99 Luminosity measurement What is the beam background environment?
Beam calorimeter Not considered in GLC detector At ILC, background is 1/200. Need serious consideration Careful design needed not to make back-splash to VTX Minimum veto angle ~5mrad (?) Physics Crossing angle?
Si pair monitor Measure beam profile from r-phi distribution of pair-background Radiation-hard Si detector (Si 3D-pixel) What happens if crossing angle is 24mrad?
Detector components Vertex Detector
Relatively low B-field of Large/Huge detector requires larger radius of the innermost layer Rmin (pair background)
Detailed simulation of background (pair b.g. and synchrotron b.g. ) is necessary to determine Rmin and beam pipe radius
R&D for thin wafer is very important to compensate for the degradation of I.P. resolution at low momentum due to large Rmin
TOF (?) K- separation by dE/dx of TPC has a gap in 0.9–2 GeV/c TOF system with =100ps can fill up the gap 1st layer of ECAL or additional detector ? What is the physics case?
History of ACFA detector study 1992 Dec. “JLC-I” report (JLC Detector)
2T solenoid, R=4.5m Compensating EM- and H-CAL, 2.5<R<4.0m Small-cell Jet chamber, 0.45<R<2.3m, L=4.6m
2001 Nov. “ACFA report” 2003 Sep. “GLC report” (GLC Detector)
3T solenoid, R=4m: Pair B.G. suppression Compensating EM- and H-CAL, 1.6<R<3.4m Small cell Jet chamber, 0.45<R<1.55m, L=3.1m ( Keep pt
min same as before) Degraded pt res.
2004 Aug. ITRP technology choice Good chance to re-start a new detector optimization study Regional study Inter-regional (world-wide) study Milestone: Detector cost estimation at the end of 2005
Large/Huge detector study so far
Actually, discussion on Large/Huge detector study has started before the ITRP decision Started discussion after LCWS2004 Brief presentation at Victoria US WS (Jul.2004) Presentation at Durham ECFA WS (Sep.2004) Detector full simulator (JUPITER) construction on going
Discussion on the key components has started still earlier TPC R&D for GLC detector started in 2003 R&D for the calorimeter of GLC detector optimized for PFA
(digital calorimeter) has proposed in Aug. 2003
A possible modification from GLC detector model
Larger Rmax (1.552.0m) of the tracker and Rin (1.62.1m) of ECAL TPC would be a natural solution for such a large tracker
Keep solenoid radius same:
Somewhat thinner CAL (but still 6), but does it matter? Use W instead of Pb for ECAL absorber
Effective Rm: 25.5mm 16.2mm (2.5mm W / 2.0mm Gap) Small segmentation by Si pad layers or scintillator-strip layers
Put EC CAL at larger Z (2.05m2.8m) Longer Solenoid Preferable for B-field uniformity if TPC is used
It is preferable Zpole-tip < l* (4.3m?) both for neutron b.g. and QC support (l* :distance between IP and QC1)
A possible modification from GLC detector model
New faces Si Endcap Tracker Si Outer Tracker Beam Calorimeter TOF
Basic design concept
Performance goal (common to all det. concepts)
Vertex Detector:
Tracking:
Jet energy res.:
Detector optimized for Particle Flow Algorithm (PFA) Large/Huge detector concept
GLC detector as a starting point Move inner surface of ECAL outwards to optimize for PFA Larger tracker to improve pt/pt
2 Re-consider the optimum sub-detector technologies based on th
e recent progresses
EEE
pp
pIP
tt
/3.0/
105/
sin/105)(52
2/3
Optimization for PFA
Jet energy resolution jet
2 = ch2 +
2 + nh2 + confusion
2 + threashold2
Perfect particle separation: Charged-/nh separation
Confusion of /nh shower with charged particles is the source of confusion Separation between charged particle and /nh shower is important
Charged particles should be spread out by B field Lateral size of EM shower of should be as small as po
ssible ( ~ Rmeffective: effective Moliere length)
Tracking capability for shower particles in HCAL is a very attractive option Digital HCAL
EEjet /%15~/
Optimization for PFA
Figure of merit (ECAL): Barrel: B Rin
2/ Rmeffective
Endcap: B Z2/ Rmeffective
Rin : Inner radius of Barrel ECAL Z : Z of EC ECAL front face (Actually, it is not so simple. Even with B=0, photon energy inside a cer
tain distance from a charged track scales as ~Rin2)
Different approaches B Rin
2 : SiD B Rin
2 : TESLA
B Rin2 : Large/Huge Detector
Effective Moliere Length
Absorber W : Rm ~ 9mm Pb : Rm ~ 16mm
Gap : Sensor + R.O. elec + etc.
xa xg
Effective Moliere Length = Rm (1+xg/xa)
Central Tracker
Figure of merit:
samplings ofNumber :
length Tracking :
field Magnetic :
resolution Spatial :
4
7203.3 )(22
n
L
B
nBLtptp
n is proportional to L if sampling pitch is constant
5.22
1
BLp
p
t
t
Merits and demerits of Large/Huge detector Merits
Advantage for PFA Better pt and dE/dx resolution for the main tracker Higher efficiency for long lived neutral particles (Ks, , and un
known new particles) Demerits
Cost ? – but it can be recovered by Lower B field of 3T (Less stored energy) Inexpensive option for ECAL (e.g. scintillator)
Vertex resolution for low momentum particles Lower B requires larger Rmin of VTX because of beam background
(IP)~5 10/(psin3/2) m is still achievable using wafers of ~50
m thick
Comparison of parametersSiD TESLA JLC GLC GLD [1] LD
Solenoid B(T) 5 4 2 3 3 3
Rin(m) 2.48 3.0 4.25 3.75 3.75 3.7
L(m) 5.8 9.2 9.1 6.8 9.86 9.4
Est(GJ) 1.4 2.3 1.1 1.8 1.7
Main Tracker
Rmin (m) 0.2 0.36 0.45 0.45 0.4 0.5
Rmax(m) 1.25 1.62 2.3 1.55 2.0 2.0
BL2.5 5.7 7.1 9.3 3.8 9.7 8.3
m 7 150 100 85 150 150
Nsample 5 200 100 50 220 144
pt/pt2 3.6e-5 1.5e-4 1.3e-4 2.9e-4 1.2 e-4
1.6e-4
[1] GLD is a tentative name of the Large/Huge detector model. All parameters are tentative.
Comparison of parametersSiD TESLA JLC GLC GLD LD
ECAL Rin (m) 1.27 1.68 2.5 1.6 2.1 2.0
BRin2 8.1 11.3 12.5 7.7 13.2 12.0
Type W/Si W/Si Pb/Sci Pb/Sci (W/Sci) Pb/Sci
Rmeff (mm) 18 24.4 21.3 25.5 16.2 21.3
BRin2/Rm
eff 448 462 588 301 817 565
Z (m) 1.72 2.83 2.9 2.05 2.8 3.0
BZ2/Rmeff 822 1311 792 494 1452 1271
X0 21 24 29 27 27 29
E+H
CAL
5.5 5.2 6.9 7.3 6.0 6.9
t (m) 1.18 1.3 1.5 1.8 1.4 1.7
Detector size
Area of EM CAL
(Barrel + Endcap) SiD: ~40 m2 / layer TESLA: ~80 m2 / layer GLD: ~ 100 m2 / layer (JLC: ~130 m2 / layer)
• EM Calorimeter
Global geometry(All parameters are tentative)
Global geometry
Global geometry
GLD is smaller than CMS “Large” is smaller than “Compact”
Detector components
TOF (Cont.)
K-
Sep
ara
tion
()
Momentum (GeV/c)
Assumptions:TOF)=100psL=2.1mdE/dx)=4.5%
Full Simulator
Installation of a new geometry into a full simulator “JUPITER” is under way
Charged – separation
Simulation by A. Miyamoto Events are generated by Pyt
hia6.2, simulated by Quick Simulator
Particle positions at the entrance of EM-CAL
Advantage of Large/Huge detector is confirmed
Inconsistent with J.C.B’s result need more investigation
( )cutall events
all events
E d d
FE
dcut
F
Charged – separation
Simulation by J.C. Brient (LCWS2004)e+e- ZH jets at Ecm=500GeV
SD (6T)
TESLA (4T)
Magnet
ANSYS calculation by H.Yamaoka Field uniformity in trackin
g region is OK
Geometry of muon detector is tentative. More realistic input is necessary
1 .241187 .72356 1.688 2.171 3.135 3.618 4.583 5.547 6.03 6.994 7.477 8.442 8.924 9.889 10.853 11.336 12.301 12.783 13.748 14.712 15.195 16.16 16.642 17.607 18.089 19.054 20.019 20.501 21.466 21.948 22.913 23.877
1111111111
mmmmdzBz
Brz28.1max
0
Other studies
See presentations in parallel sessions and http://ilcphys.kek.jp/
Summary Optimization study of Large/Huge detector concept has just started GLC detector is the starting point of the Large/Huge detector, but its
geometry and sub-detector technologies will be largely modified A key concept of Large/Huge detector is optimization for PFA A milestone of this study is the detector cost estimation scheduled
at the end of 2005. A firm report backed up with simulation studies and detector R&D should be written
A lot of jobs including clarification of physics requirements, detector full/quick simulation, and detector R&D are awaiting us
Please join the Kick-off meeting:Date: Nov. 10 Time: 17:30 - 19:30 Place: Room 204
Beam Calorimeter is placed in the high background region
Same sign
Opposite sign
by T.AsoGLC Parameter, B=4T
Pair background track density
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