Calibration of the PHENIX Lead Scintillator Calorimeter H.Torii for the PHENIX Collaboration Kyoto...

Calibration of the PHENIX Lead Scintillator Calorimeter

H.Torii for the PHENIX Collaboration

Kyoto Univ./RIKEN

Contents•Lead Scintillator Calorimeter(PbSc)•Test beam results•Calibration in PHENIX configuration•Summary

L. Aphecetche, T. Awes, S. Bathe, H. Baumlsching, A. Bazilevsky, S. Belikov,S. Botelho, S. Chernichenko, D. Bucher, H. Buesching, G. David,

A. Denisov, D. d,Enterria, H. Delagrange, A. Durum, R. Glasow, Y. Goto, M. Grosse-Perdekamp, S. Fokin, H. Hamagaki, K. Imai, M. Ippolitov,

E. Kistenev, S. Kametani, V. Kochetkov, V. Manko, G. Martinez,T. Matsumoto, Y. Melnikov, S. Mioduszewski, S. Nikolaev, A. Nyanin,

V. Onuchin, K. Oyama, Y. Schutz, A. Soldatov, T. Peitzmann, K. Reygers,T. Sakaguchi, R. Santo, S. Stall, P. Stankus, T. Thomas, H.Torii, A.Usachev,

A. Vinogradov, M. Volkov, S. White , C. Woody, G. Youngfor the PHENIX Collaboration

Special thanks for pictures: E.Kistenev,G.David,A.Bazilevsky

Lead Scintillator Calorimeter(PbSc)

Size(cm x cm) 5.52 x 5.52

Depth(cm) 37.5

Number of towers 15552

Sampling fraction ~ 20% cov. 0.7 cov. 90+45deg/ mod 0.011 / mod 0.011

Molière Radius ~ 3cm

Shashlik type calorimeter Scintillator plates 55.2x55.2x1.5mm Lead plates 110.4x110.4x4mm

Shish-kebab geometry wave shifter fiber readout6x6 fibers 1 PMT = 1 tower2 x 2 towers = 1 module6 x 6 module = 1 super module6 x 3 super module = 1 sector

37.5cm 11cm

Very fine segmentation

Energy linearity and resolution

Energy resolution2.1%8.1%/E(GeV)

nucl-ex/0202009

Light attenuation in the WLS fibers(effective Latt~100cm)

Energy leackage

Timing and Position resolution

• Timing resolution

Position resolution

nucl-ex/0202009

• We measured hadron energy response at test beam– 0.3-2GeV/c ,K,p– 40GeV/c +

• Two structure– Ionization

• 270MeV for 1GeV/c pi

– Hadronic shower• Distribution from the

ionization energy to its kinematics energy.

• The measured energy of electromagnetic shower is well separated from that of hadronic shower.

1GeV/c e-

40GeV/c e+

40GeV/c +

1GeV/c +

Hadron response

nucl-ex/0202009

PHENIX Configuration

• 2 Arm 4 sectors– Lead Scintillator(PbSc)

6 sectors(15552 channels)

– Lead Glass (PbGl)2sectors (9216 channels)

• ~5m distance from collision point• ||<0.38 = 180

4m (72 towers)

Energy Calibration Strategyin PHENIX configuration

• Before installing into PHENIX configuration, all towers are calibrated using cosmic muon traversing laterally.(1998??)

• The calibration parameters are transported into PHENIX configuration by laser monitoring system.– The procedure is well established through several beam test

• Remained misalignment is corrected using charged particle from collision traversing lengthwise

• The absolute energy scale is obtained by physics signal 0 mass– E/p– Ionization energy

Energy calibration• All towers calibrated by ionization

energy of cosmic muon traversing laterally– 42MeV

• Additional misalignment is calibrated by charged traversing lengthwise– 270MeV

Axial’s

Laser monitoring system• UV laser (YAG laser) is used for

calibration and monitoring system– The light intensity is monitored with

PIN diodes at each intermediate splitter that are used for normalization.

– Light is injected into each module through a “leaky fiber” to simulates an electromagnetic shower

• Laser monitoring system works for– Transportation from cosmic muon

calibration into PHENIX configuration

– Trace of time drift

Absolute energy calibrationThree independent measurement results in

2% accuracy of absolute energy calibration

Ionization energy 0 mass electron E/p

Timing calibration• Strategy

– Slewing correction is obtained by laser and photon.

– Time zero is adjusted using photon sample purified by shower shape cut.

• Timing measurement is very important in heavy ion collision– to reduce slow hadron

contribution

Currently, time resolution is

~400psec for 0.5GeV work in progress

Before correction

After correction+ photon PID

• Timing measurement is also important for hadron physics– For run1, -K separation up

to 0.8GeV/c

0.7-0.8GeV/c

Hadron PID

0 measurement

m(0) = 135.1 MeV/c2

m(0) = 10.3 MeV/c2

m() = 547 MeV/c2

m() = 34 MeV/c2

pT = 1.5 – 2.0Gev/c

Subtraction by event mixing

Run1 Au+Au sNN =130GeV

10% Central events

Run2 p+p sNN =200GeV

pT = >3.5Gev/c

Pi0 measurement is successful from p+p to Au+Au collision

Summary• Test beam results

– Energy linearity and resolution(2.1%8.1%/E)– Timing resolution, Position resolution(1.4mm+5.9mm/E), Hadron

rejection

• PHENIX configuration– The relative energy for all towers is calibrated using the ionization

energy of a cosmic muon traversing laterally and that of a charged pi traversing lengthwise

– Gain drift during run is corrected by laser monitoring system.– The absolute energy scale is 2% accuracy from

• E/p 0 mass• Ionization energy

– Time measurement • Hadron PID shows /K separation up to 0.8GeV/c in Run1

Calibration of the PHENIX Lead Scintillator Calorimeter H.Torii for the PHENIX Collaboration Kyoto...

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