FoCal Project in ALICE Yota Kawamura for the ALICE FoCal collaboration TCHoU workshop 218/3/15 1
Outline Introduction of FoCal Project Motivation Detector design The result of past test beam (214~216) Activity in 217 Production of new Si detector Test beam at ELPH Summary TCHoU workshop 2
FoCal project ALICE detector LHC FoCal Forward Calorimeter Electromagnetic calorimeter installed in the forward direction (3.3 <η <5.3) ALICE upgrade plan Install finished machine in 224 (LS3) Experimental verification of CGC by direct photon measurement FoCal in ALICE detector TCHoU workshop 3
Motivation The time scale of collision What is the nucleon before the collision? Bjorken-x Parton distribution as a function of Bjorken-x at Q 2 = 1 GeV 2 x = 2p T p s e y Small-x x apple 1 4 CGC occures Nuclear form before nuclear collision Model Color Glass Condensate(CGC) the saturation of gluon Access to information in the initial stage of collision Low x, that is at high energy and forward region TCHoU workshop 4
Direct Photon measurement Experimental validation Probe Direct (isolated) photon NLO pqcd CGC model Direct photon R_pA η = 4, p+pb, s = 8.8 TeV Required performance 1, high position resolution enough to separation γ/π 2, energy measurement with wider dynamic range Y (mm.) 15 1 5 5 1 15 5GeV direct photons longitudinal depth : 5X 15 1 5 5 1 15 X (mm.) Y (mm.) 15 1 5 5 1 15 5GeV π decay photons longitudinal depth : 5X 15 1 5 5 1 15 X (mm.) 1, HGL(high Granularity Layer) High position resolution (MAPS detector) 2, LGL(Low Granularity Layer) Energy measurement (PAD detector) TCHoU workshop 5
FoCal design LGL HGL Si/W sandwich constructer W: Absorber 1X = 3.5 mm(1layer) RM = 9.3 mm 2 types of Si sensor 1. LGL(Low Granularity Layer) Si Pad 1Pad = 1 1 cm2 1layer = 64 Pads(8 8) Energy measurement 2. HGL(High Granularity Layer) Monolithic Active Pixel Sensors (MAPS) 1pixel = 3 3 µm2 digital readout High position resolution University of Tsukuba LGL Utrecht Univ. HGL Straw man design TCHoU workshop 6
Performance evaluation of the prototype counts/n evts.12.1.8.6 1 GeV 2 GeV 3 GeV 4 GeV 5 GeV counts/n evts.6.5.4.3 13 GeV 11 GeV Energy Resolution [%].4.2 1 2 4 6 8 1 ADC sum (ch) 3 25 2 15 1 ADC distribution test beam 216 test beam 215 ideal simulation simulation(with dead ch) 2 2 y= (9.7) +( 25.7 ) E 2 2 y= (5.1) +( 12.8 ) E 2 y= (1.1) +( 1.7 ) E 2 3.2.1 2 4 6 8 1 1 12 14 16 18 2 ADC sum (ch) Take data up to 13GeV Energy resolution 15% 6 5 Test beam at CERN SPS in 216 2 4 6 8 1 12 14 Beam Energy [GeV] Test beam ORNL (Oak Ridge National Laboratory) prototype until 214 216 next MIP measurement and more wider dynamic range Improve energy resolution 7
Activity in 217 Trial in this year Production new prototype (The first attempt of Japan FoCal group) Ongoing Evaluation of basic characteristics Si-Pad Design optimization Si detector production Test beam (at Tohoku univ. ELPH ) MIP ~ Low Energy measurement 1ch monitor PD for basic characteristics test Si-Pad detector Si detector (8 8 ch) 8
Production Flexible printed circuits Si PAD made by Hamamatsu 1cm 2 Pad size 8 8 cell Picture when boning Bonding machine Bias circuit and read line to each cell, GND connect with silicon with wire of several 1 µm thickness 9
Readout System APV25(CERN RD51) SRS(Scalable Readout System) (CERN RD51) readout chip preamp, shaper 128 ch : output Sampling frequency:4mhz 5Gains: 8,9,1,11,12% ADC Board:12bit 16ch ADC 128 16 = 248ch FEC Board: front-end Control of digital information by FPGA on FEC UDP communication by GbE HDMI Detector GbE SRS AD conversion Front end mmdaq(pc) Online monitor Data taking TCHoU workshop 1
Set up beam JIG, Electric Stage Detector : 1 1 cm : 4 4 mm W plate detector W plate (3X) Trigger scintillator Date: December 15-22 at ELPH in Tohoku University 8 MeV/c e + beam Generate beam trigger with coincidence of three scintillator Place 3X tungsten plates in front of the detector to raise a shower (take data with W on and off) TCHoU workshop 11
Result MIP response 16 1 MIP 14 12 1 8 2 MIP 6 4 3 MIP? 2 2 4 6 8 1 12 14 16 18 2 GEANT4 simulation 1 Pad ADC distribution 1 Events that two electrons, three entered in Pad, can also be observed (peak is proportional to number of electron) Consistent with GEANT4 12
Characteristics of each channel MIP ADC (ch) 5 45 4 35 3 25 2 15 1 5 1 2 3 4 5 6 7 ch MIP ADC channel as a function of ch 8 7 6 5 4 3 2 1 1 2 3 4 5 6 7 8 8 8 hit map ADC (ch) 22 21 2 19 18 17 16 Without tungsten : beam behave as MIP Variation < 1 % (Pad and electronics characteristics? ) Signal is smaller at the edge -> Because of dark current? or signal attenuation due to wiring length? 13
Efficiency Efficiency = hits / entries hit Number detected by pad entries Number detected by the trigger number of hits Total efficiency is about 97% The beam is not narrowed down to 1 channel TCHoU workshop 14
Summary FoCal project Electromagnetic calorimeter scheduled to be installed in front of ALICE detector Silicon Detector production for the first time ELPH test Successful observation of MIP signal the variation of PAD < 1 % efficiency 97 % Next Production of prototype for real machine by increasing the layer of silicon as a calorimeter Dynamic range expansion to enable observation of high particle energy in the forward direction TCHoU workshop 15
APV 4MHz 25nsec APV128 ch ADC TCHoU workshop 18
MIP 12 1 2 χ / ndf 24.7 / 186 Prob.1653 Constant 61.2 ± 18. MPV Sigma 195.3 ± 1. 23.69 ±.57 8 6 4 2 2 4 6 8 1 12 14 16 18 2 1MIP W TCHoU workshop 19
Linearity ADC sum value [ch] 8 7 6 5 4 3 2 1 Energy Dependence 1 2 3 4 5 Energy [GeV/c] ADC_SUM [ch] 1 1 9 8 7 6 5 4 3 2 1 3 4 3 ADC [ch]=5.57 1 E [GeV]+3.52 1 [ch] 2 4 6 8 1 12 14 Ratio 1.8 Beam 1.6 Energy [GeV] 1.4 1.2 1.98.96.94.92 1 2 3 4 5 Energy [GeV/c] TCHoU workshop 2
Longitudinal shower growth ADC_SUM [ch](data) 35 3 25 2 15 1 5 3 1 13 GeV 11 GeV 2 4 6 8 1 12 14 16 18 2 Radiation length [X ] 7 6 5 4 3 2 1 deposit energy [MeV](simulation) 21