simulation study of ion back flow for the alice-tpc upgrade
DESCRIPTION
Simulation study of Ion Back Flow for the ALICE-TPC upgrade. Taku Gunji Center for Nuclear Study University of Tokyo. RD51 Collaboration Meeting at SUNY, 5.10.2012. Outline. ALICE GEM-TPC upgrade Measurement of IBF in RD51 Lab . at CERN Measurement of IBF at TUM - PowerPoint PPT PresentationTRANSCRIPT
Simulation study of Ion Back Flow
for the ALICE-TPC upgradeTaku Gunji
Center for Nuclear Study University of Tokyo
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RD51 Collaboration Meeting at SUNY, 5.10.2012
Outline• ALICE GEM-TPC upgrade • Measurement of IBF in RD51 Lab. at
CERN• Measurement of IBF at TUM• Status of IBF simulations on June 2012• Update since then
– IBF vs. charge up of GEM– IBF vs. space-charge above GEMs
• Summary and Outlook
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ALICE GEM-TPC upgrade• LoI of the ALICE upgrade
– https://cdsweb.cern.ch/record/1475243/files/LHCC-I-022.pdf• High rate capability
– Target: 2MHz in p+p and 50kHz in Pb-Pb collisions• Plan for the ALICE-TPC upgrade
– No gating grid and continuous readout• Inherited the idea from ILC/PANDA GEM-TPC [arXiv:1207.0013]
– MWPC readout will be replaced with GEM. – Keep current gas composition: Ne(90)/CO2(10)
• Issues for the GEM-TPC upgrade – Stability of GEM operations (gain, charge up, discharge, P/T)
• Prototype GEM-TPC will be installed/tested at ALICE in 2012.– Good dE/dx resolution for the particle identification
• ~5% for Kr by PANDA GEM-TPC. Comparable to the current ALICE-TPC.• Prototype will be tested in 2012 at CERN-PS T10 beamline
– Ion back flow to avoid space-charge distortion• Requirement < 0.5%• Measurement using test bench in CERN, Munich and Japan• Simulations to search for the optimal solutions
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IBF measurements at CERN
Ampteck Mini X-ray tube
Ag target: Ka=22KeVRate (Ar(70)/CO2(30))= 5e7 estimated by Id
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C. GarabatosY. Yamaguchi
• Systematic measurement is on-going at RD51 lab.
Rate, # of seeds/hole5
• Estimation of rate/hole, # of seeds/hole in the lab test and Pb-Pb 50kHz collisions.– Lab. test at CERN
• X-ray rate: ~105Hz/mm2,# of seeds: ~1000• # of seeds/hole (4cm driftdiffusion~500um)
– 1000/(500um)2*(100um)2 = 40 (or less ~ 20)• Rate/hole: ~105Hz/mm2 x (0.5mm)2 ~ 25kHz (40usec)
– Pb-Pb 50kHz• Occupancy (IROC:4x7.5mm2) = 50%• Seed electron density (Nch*100*dR/S)= 150e/cm2 • # of seeds/hole (1m drift diffusion~3mm)
– 15(e/(3mm)2) / (3mm)2 x (100um)2 = 0.02• Rate/hole (with seed):50kHz*50%*0.02 = 0.5-1kHz
(~msec)• Much relaxed conditions compared to lab. test at CERN.
Results of IBF at CERN6
• Extensive study for the parameter dependence– 0.25% can be achievable.
• Comparable to ILC/PANDA GEM-TPC– Study for Ne/CO2 (90:10)– Strong VGEM dependence
Ne/CO2/N2
M. Killenberg et al. NIM A530, 251 (2004)B. Ketzer et al. arXiv:1207.0013
Rate/Position dependence7
• X-ray rate dependence and tube position (from GEM1) dependence– Current of primary ions is linear to tube current.– IBF strongly depends on:
• (VGEM)• Rate • Position from GEM1
– Less diffusion for 1.5cm.– IBF is strongly affected by local charge density???• space-charge/recombination
Caveat: The conditions of this measurement are far away from the conditions expected in 50kHz Pb-Pb.
IBF Measurements at TUM8
• Systematic and simultaneous studies of IBF, gain, and energy resolution.
• Reading out currents from all electrodes.Caveat:Rate of X-ray is ~10% of that at CERN
B. Ketzer, A. Honel from TUM
Results of IBF at TUM9
• VGEM dependence – Gain increases as expected. Resolution gets better
as higher VGEM – No VGEM dependence of IBF • Due to smaller rate (10%)?
resolution
gain
IBF
IBF studies in simulations• First results were presented at the last meeting on
June 2012.• Discrepancy between measurements and
simulations.– Measurements at CERN: strong VGEM dependence– Simulations: No VGEM dependence (agree with TUM results)
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2 GEMs2 GEMs
Possible Reasons• Charge-up on the Kapton surface– CERN GEMs (bi-conical shape) are used in the
measurement.– Measurement with cylindrical GEM holes will be
done in the lab.• Space-charge– Clear VGEM, rate and position dependence at CERN
• Larger local electrons/ion density leads to smaller IBF?
• Since x-ray rate/hole is ~25kHz at CERN Lab., remaining ions in the space affects IBF?
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Charge-up simulations• Simulation setup
– 1 GEM (50um. Bi-conical). HV=400V (gain=50). Ar/CO2=70/30
– Kapton surface area is divided into 16 segments. • Procedure
– 1: Generate 100 avalanches. Then calculate # of ions and electrons absorbed in each segment.
– 2: Put (these # of electrons and ions x 5000) into Kapton surface and calculate electric field.
• Equivalently, 100x5000 (=5x105) seeds in one cycle
– 3: Repeat 1 & 2 for many times.
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Accumulation of charges in Kapton
• Nelc-Nions at each segment vs. iteration cycle• Nelc/Nions are saturated at 0.5-1x107 seeds at
the gain of 50 (HV=400).
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Lower GEM
Ed
0/16
16/16
Seeds
electrons electrons
ions ions
Accumulation of charges in Kapton
• Nelc-Nions at each segment vs. iteration cycle• Nelc/Nions are saturated at >1x108 seeds at the
gain of 50 (HV=400).
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Lower GEM
Ed
0/16
16/16
Seeds
electrons electrons
ions ions
Upper GEM
Gain vs. cycle• 10-20% increase of Gain is seen.
– Due to many electrons at the bottom of Kapton, potential around there gets lower and electric field gets larger.• Gain increases. Avalanches happen more at the bottom.
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Average electron creation Point in z [cm]
Total electrons Electrons in induction
IBF vs. cycle• No big change of IBF with charge up– Ions escaping to drift space come from the center of the hole in R.– No big change of <R> of creation points.
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Average avalanche pointsIn R [cm]
IBF
RZ
Space charge simulation• Very simple simulation for space-charge• Strategy– Make volume to put ions.
• Volume : 70 (pitch/2, X) x 70*sqrt(3) (Y) x 100 (Z) um3
– 100um is chosen since the spread of ions (after avalanches) is ~100um (more or less) above GEM.
• Replica of this volume by mirror symmetry• 10 volumes above GEM covering [0, 1mm] from top
of GEM– Put ions (from 0-105~106) in one of 10 volumes– Electric field is calculated.– Make avalanches
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DZ=100um
1mmions
Electric Field above GEM• Examples on the change of the field – 0, 105 and 106 Ions in [0, 100um] above GEM.
• 10usec after avalanches– Field Strongly depends on the number of ions.– More ions are curled up and absorbed at the
electrode with larger Nions??
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Nions=0 Nions=105 Nions=106
Ed=0.4kV/cm
Gain and IBF vs. VGEM(1GEM)• Ions at [0, 100um] above GEM (Ed=0.4kV/cm)• Gain and IBF vs. VGEM for various Nions
– Gain doesn’t change. IBF does, especially Nions>104
– IBF doesn’t change for Nions<104.• Good direction to the meas. (VGEM Nions IBF)
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Nions=104
Nions=105
Gain and IBF vs. VGEM(1GEM)• Ions at different location above GEM
(Ed=0.4kV/cm)• IBF is drastically changed with Nions>104
• Less effective if ions are on more upper of GEM.
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Nions=0, 102, 103, 104, 2x104
Gain and IBF vs. VGEM (2GEM)• 2 GEMs (Ed=0.4kV/cm, Et=3.5kV/cm). • Ions at [0, 100um] “only” above GEM2• Gain changes by 20% (not understood)• IBF changes for Nions>105
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Nions=105
Nions=4x105
Gain and IBF vs. VGEM (2GEM)• 2 GEMs (Ed=0.4kV/cm, Et=3.5kV/cm). • Ions at different locations “only” above GEM2• IBF changes for Nions>5x104
– Onset depends on the underlying electric field
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Nions=0, 103, 104, 5x104, 1x105,
1.25x105, 1.5x106
More dynamical simulations(?)• So far, ions are put in [Z, Z+100um] above
GEM1/GEM2.• Make spatial ion profile for each10usec, 30usec,
60usec, 100usec steps after avalanches. • Ions are swept away from T1 quickly (40usec) and
stays above GEM1 due to lower electric field.
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Et = 3kV/cm Ed = 0.4kV/cm Et = 3kV/cm Ed = 0.4kV/cmIon profile per one seed (Ar/CO2=70/30, Gain~1000)
electronelectron
More dynamical simulations(?)• Ion spatial distribution for 10usec (100kHz) and
100usec (10kHz) separated avalanches– Many ion clouds on T1/drift space for the case of avalanches
at every 10usec. No ions in T1 for the avalanches at every 100usec.
• Make new field with these profile * Nseeds
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Ion profile per one seed (Ar/CO2=70/30, Gain~1000)Et = 3kV/cm Ed = 0.4kV/cm Et = 3kV/cm Ed = 0.4kV/cm
electronelectron
10usec spacingfor avalanches
100usec spacingfor avalanches
IBF vs. rate• Lab. test conditions (20-40 seeds/hole and ~25kHz
rate/hole)• IBF vs. time spacing between avalanches (rate/hole)• Clearer rate dependence for higher gain
– IBF gets smaller with higher rate/higher gain
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Seed/hole=3 Seed/hole=10 Seed/hole=25
IBF vs. Nseed26
30usec spacing
60usec spacing
100usecspacing
• Lab. test conditions (20-40 seeds/hole and ~25kHz rate/hole)
• IBF vs. Nseed (related to diffusion)• Clearer Nseed dependence for higher gain
– IBF gets smaller with higher Nseed/higher gain
30usec spacing (30kHz) 60usec spacing (16kHz) 100usec spacing (10kHz)
Nseed=10Nseed=20Nseed=15 Nseed=20
Nseed=40
IBF vs. VGEM• Lab. test conditions (20-40 seeds/hole and ~25kHz
rate/hole)• No influence for smaller gains (HV=350)• Steep change for Nseed with higher gain• Trend is ok. But still difference in magnitude
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Summary and Outlook• IBF studies have been conducted at CERN/TUM.
– 0.25% can be achievable. – More studies on rate and position (spread of seed)
dependence are on-going.• IBF simulation studies are on-going.
– Still not yet understood the discrepancy between measurements (lab. test at CERN) and simulations.
– Charge-up and space charge are accounted. – Space-charge has influence on IBF, especially N ions>104
(Ed=0.4kV/cm) and 105 (E=3kV/cm).• Clear rate / gain dependence. • Partially explain VGEM dependence of IBF measured at CERN
– More dynamical simulations• Currently ions in the space contribute “only” to the field.• Recombination with the seeds? More precious dynamics.
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Thanks to C. Garabatos, Y. Yamaguchi, B. Katzer, V. Peskov, R. Veenhof, and all of ALICE-TPC upgrade team
Backup slides
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Gain and IBF vs. VGEM (2GEM)• 2 GEM configurations (Ed=0.4kV/cm,
Et=3.5kV/cm). • Now, I put ions on the upper of both GEM1 and
GEM2.– Ions are put [0, 100um] above GEM1 and GEM2.– Assumption:
• Nions at GEM1 = 0.2*Nions at GEM2. – Assuming that most of the ions are from GEM2.– 0.2 = IBF of single GEM with Ed=0.4kV/cm.
– Distance between GEM1-GEM2 = 2mm• vd for Ions ~ 5um/usec. • 2mm spacing => 400usec. • If one seed come at 2.5kHz per hole, ions above GEM1 and GEM2 are distributed with 2mm spacing.
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DZ=100um
2mm
DZ=100umGEM1
GEM2
Gain and IBF vs. VGEM (2GEM)• 2 GEMs(Ed=0.4kV/cm, Et=3.5kV/cm). • Ions at [0, 100um] above GEM2/GEM1• Gain changes by 20% and IBF changes for
Nions>5x104
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Gain and IBF vs. VGEM (2GEM)• 2 GEMs (Ed=0.4kV/cm, Et=3.5kV/cm). • Ions at different locations above GEM2/GEM1• IBF changes for Nions>5x104
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Nions(GEM2, GEM1)=(0,0), (104, 2x103), (5x104, 104), (105, 2x104)
[100, 200um] above GEM1/GEM2 [500, 600um] above GEM1/GEM2
Play with the numbers -I• Qualitatively, space-charge can explain steep
dependence of IBF vs. VGEM as seen in the measurements. – Higher VGEM higher Gain higher space-charge effects less
IBF.• Quick play with the numbers
– Gain=400 (M~800) at VGEM=400– # of seeds = 700 (22keV/30eV)– Spread due to diffusion
• 600 um for 4cm drift– (300 um/sqrt(cm))
• 5% in 100um x 100um?• 35 seed/hole?
– # of ions = 35 x 800(M) = 3x104?• This is between red and green…• Nions = 2.5x105 is unrealistic in the measurements?• Rate? (Rate=5kHz/mm2? 200usec/avalanches per hole?)
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Movement of ions 34