1. R&D status of Scintillator
8th ACFA Workshop
Daegu, Korea
Youngdo Oh
Kyungpook National University
Junsuk Suh, Youngdo Oh, Kihyun Cho, Donghee Kim : Kyungpook National University
Intae Yu : SungKyunKwan Univesity
Soobong Kim : Seoul National University

2. Current R&D Status
At first, the pure polystyrene bar was produced without
PPO, POPOP
The mechanical process is established
2. At second, PPO and POPOP were mixed up with polystyrene
 The 1st scintillator was produced.
3. Light yield was measured and compared with reference
scintillator

3. Plastic Scintillator extrusion is easy to make thin scintillator
Component: Polystyrene pellets + Dopants
(primary & secondary)
Dopants
Primary dopants (blue-emitting)
PT(p-Teraphenyl), PPO(2,5-biphenyloxazole)
1-1.5% (by weight) concentration
Secondary dopants (green-emitting)
POPOP(1,4-bis(5-Phenyloxazole-2-yl)benzene),
bis-MSB(4-bis(2-Methylstyryl)benzene)
% (by weight) concentration
Production : Extrusion
extrusion is easy to make thin scintillator

4. Plastic Scintillator – how does it work ?
Excitation of bas plastic by radiation
Base plastic
10-8 m
Foster energy transfer ( resonant dipole-dipole interaction)
PPO (~1%)
Emit UV ~340nm
10-4 m
photon
Absorb UV photon
POPOP(~0.05%)
Emit blue ~400nm
photon
Detector (PMT, photo diode …. )

5. Extrusion Process All the work is done at one facility → reduces costs
By removing its exposure to another high temperature cycle → reduces hits history of the product
→ eliminates an additional chance for scintillator degradation

6. Die and Materials Polystyrene : 3 kg PPO : 1.3 % POPOP : 0.03%
Die profile
4cm
1cm
2mm
1.2 mm
Mixture of dopants
Polystyrene : 3 kg
PPO : 1.3 %
POPOP : 0.03%

7. First Batch from Misung chemical
At first, We try to produce polystyrene bar without PPO
and POPOP to make sure the chemical and mechanical
process.
TiO2 was coextruded to make reflector.
At 2005/5/17 , Misung launched extrusion for scintillator
The first product had big groove  die had minor problem
At 2005/6/9 , the excellent bars were produced.
At 2005/7/7, the 2nd bacth has PPO, POPOP.
Evolution

8. 2nd Production PPO and POPOP were mixed up 110 cm bars were produced
We produced this batch in air

9. Comparision of transparency
Oxidation made the sample opaque
because of production in air.
Reference
samples
Polysyrene
bar
New samples

10. Scintillator test setup
FAN
IN-OUT
Logic
unit
Gate
Generator
100 ns
Delay
VME
readout
Disc
5 reference samples and new samples with the same geometrical shape and size were used to compare light yield
Typical cosmic ray
From reference sample + WLS

11. Preparation of test samples

12. Light Yield Measurement
Trigger : threshold = 100mV , Gate=150ns
New sample
New scintillator bars (5 samples)
<ADC counts> =  25.1
Reference scintillator bars(5samples)
<ADC counts> = 76.9
ADC counts
Reference sample
Relative Light Yield of new samples
shows 40.1% of reference samples
ADC counts

13. Light Yield Measurement
Trigger : random trigger (1000Hz) , Gate=150ns (amplifier used : x100 )
New sample
New scintillator bars (5 samples)
<ADC counts> =  24.9
Reference scintillator bars(5 samples)
<ADC counts> = 56.9
ADC counts
Reference sample
Relative Light Yield of new samples
shows 42.3% of reference samples
ADC counts

14. Light Yield Measurement
Trigger : random trigger (1000Hz) , Gate = 2 s
(amplifier not used)
New sample
New scintillator bars (5 samples)
<ADC counts> =  3.5
Reference scintillator bars(5 samples)
<ADC counts> = 79.1  8.4
ADC counts
Reference sample
Relative Light Yield of new samples
shows 33.5% of reference samples
ADC counts

15. Light Yield Measurement
Pico ammeter is used
Reference samples
Average = 4.35
RMS = 0.39
New samples
Average = 1.59
RMS = 0.18 A
Sample ID
Relative Light Yield of new samples shows 36.6% of reference samples’ one.

16. Light Yield Measurementcm
Refernce sample
New sample

17. Summary and Plan First Polystyrene bar produced with PPO and POPOP
 The mechanical process is established
Light yield measued for new and reference samples
 new sample shows ~40% light yield of reference sample
 low light yield because of oxidation in air
To avoid oxidation, we need to change process
 under Nitrogen or vaccum
If we get good light yield, then we will change die to
produce “thin” scintillator for tile calorimeter
 thickness : 3mm , width : 1cm