Transcript Diodes

Summer Student
Presentation
Radiation Monitoring
with commercial
p-i-n diodes
BPW34F
Summer Student Project of Kim Temming
Supervisors:
Michael Moll
Maurice Glaser
Friday, 3rd of September
By Kim Temming
1
Outline




purpose of my project
diode BPW34F / BPW 34
how to measure radiation with this diodes?
history of my measurements
 irradiations
 first setup
 measurements / results
 problems
 new setup
 measurements
 first results
 problems
 first conclusions
 outlook
Summer Student Presentation
Kim Temming
2
Purpose of my Project
 investigate the possibility to use commercial BPW 34 p-i-n
diodes as dosimeters for LHC experiments and irradiation
facilities
 advantages
 commercial product: low costs (1.60 €)
 robust and easy to handle
 large fluence range (1012 – 1015 p/cm2)
 measuring NIEL (displacement damage)
 disadvantages
 needs qualifying
 temperature & fluence dependence
 annealing
 readout scheme
 commercial product (no influence on production)
Summer Student Presentation
Kim Temming
3
Diode BPW34F / BPW34
 commercial SI-pin-diode / cheap
 BPW34 photosensitive from 400nm to 1100nm
(BPW34F: 950nm)
 applications:
 IR remote controls
 photointerruptors
 control and drive circuits
BPW34
-
photosensitive area
+
BPW34F
Summer Student Presentation
Kim Temming
4
How to measure radiation?
 increase of voltage with fluence for constant current when
biased in forward direction
Summer Student Presentation
Kim Temming
5
My Work: Irradiations
 102 diodes were irradiated with 24 GeV/c PS proton beam
 50 BPW34F from USA
 1.0 E15, 0.5 E14, 0.3 E14, 1.0 E14, 0.5 E13, 0.3 E13,
1.0 E13, 0.5 E12, 0.3 E12, 1.0 E12 (all in p/cm2)
 22 BPW34F from MALAYSIA
 1.0 E15 ppcm2, 1.0 E14 p/cm2
 BPW34 Siemens, BPW34 Osram and BPW34FS
 each 5 pieces 1.0 E13 p/cm2
 each 5 pieces 1.0 E14 p/cm2
 irradiations successful in
limits of 20% discrepancies
to wanted fluence
(+ca. 8% errors on values)
Summer Student Presentation
Kim Temming
6
First Setup
 aluminium box / completely dark
(diodes are sensitive to daylight!)
 Keithley 2400
 set current / read voltage
 sensor for temperature
 inside box / 2 cm beside diode
 sensitivity: 0.1 degree celsius
 labview program
 option for constant current
 option for pulsed current
 displays graph:
voltage
time
Summer Student Presentation
Kim Temming
7
Measurements / results first setup
 VI measurements of all samples before irradiation
 current between 0.1 A and 1 mA
 results of VI measurements before irradiation:
 nearly all samples show same characteristic
 all differences between samples become larger with
higher current
diodes before irradiation
0.6600
voltage (V)
 samples from Siemens:
 old (some years)
 vary more than 20%
samples
siemens
0.5600
U at 100nA (V)
0.4600
U at 1muA (V)
U at 10muA (V)
0.3600
U at 100muA (V)
0.2600
U at 1mA (V)
95
88
81
74
67
60
53
102
43
36
29
22
15
8
1
0.1600
sample number
Summer Student Presentation
Kim Temming
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Measurements / results first setup
 dependence of the voltage on readout frequency and
readout pulse length
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


10 samples together irradiated with 1.0 E14 protons/cm2
applied current: 1 mA
pulse length varying between 1 ms and 1 s
pulse to pulse time between 60 s and 3 s
 Results of dependence on readout frequency & pulse length
Summer Student Presentation
value voltage dependent on the number of diode
different colors show different pulse-to-pulse time
voltage (V)
 not very sensitive
to pulse length
(except of constant current)
 not at all sensitive to
time between pulses
 but differences of more
than 20 % between the
different diodes
11.5
11
10.5
10
9.5
9
value voltage delay 60 s
value voltage delay 10 s
value voltage delay 3s
13
15
17
19
number of diode
Kim Temming
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Measurements / results first setup
 dependence on readout current
 ONE diode irradiated with 1.0 E14 protons/cm2
 pulse to pulse 3 s, pulse length varying
 current varying between 1 A and 100 mA
 Results of dependence on readout current
18.1
16.1
14.1
12.1
10.1
8.1
6.1
4.1
2.1
0.1
(voltage <-> applied current) for
different pulse lengths
18
0.001 mA
0.01 mA
0.1 mA
1 mA
10 mA
100 mA
16
voltage in V
voltage in V
voltage to pulse length
14
pulse length 1 ms
pulse length 10 ms
pulse length 100 ms
pulse length 1000 ms
pulse length 3000 ms (cc)
12
10
8
6
4
2
1
10
100
1000
10000
pulse length in ms
Summer Student Presentation
0
0.001
0.01
0.1
1
10
100
current in mA
Kim Temming
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Problems of first setup
 diodes are very sensitive to temperature
 measured voltage depends very much on the temperature
of diode
 temperature is measured 2 cm away from diode /
isolated by plastic and air
 possible sources of temperature differences
 changes of room temperature (air condition!)
 touching of diodes
 opening of box
 necessary to control temperature
of diode very exactly
Summer Student Presentation
22.4
temperature
 another possible explanation:
diodes show peltier effect
 cooling down by applying current
temperature - voltage
22.2
22
21.8
21.6
21.4
9
Kim Temming
9.5
10
10.5
voltage
11
11.5
12
11
New setup
 peltier element below socket of diode regulates
temperature of diode to exactly 19.3  0.01 degree celsius
 temperature read out by small temperature sensor
(operated with Keithley 2410)
 readout of diode still with Keithley 2400
 temperature displayed on web with webDAQ/100
Summer Student Presentation
Kim Temming
12
Measurements with new setup
 ONE diode irradiated with 1.0 E14 protons/cm2
 always same end value with constant current
 first no room temperature effects (outside box) visible
because of the good temperature shielding
 over night / weekend measurements
 irradiated diode
 non irradiated diode
 very temperature stable resistor
 measurements:
 applied current: 100A, constant current
 temperature measured inside and outside the box with 2
digits
 voltage measured with labview-program and Keithley
2400
Summer Student Presentation
Kim Temming
13
First results (new setup)
 irradiated diode: voltage still depending on temperature
but very sensitive
 not irradiated diode:
same results but
less amplitude
 1 k Ohm resistor
Summer Student Presentation
Kim Temming
14
Problems of temperature / Keithleys
 not completely clear yet:
 effect of temperature in diode?
 effect of room temperature in Keithleys?
 limit of keithley accuracy!
Summer Student Presentation
Kim Temming
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First conclusions
 before irradiations:
 all diodes very close together, only few discrepancies on
readout voltage
 after irradiation:
 diodes show discrepancies of up to 20% on readout
voltage
 diodes very temperature sensitive
 temperature needs to be controlled
 best readout scheme:
 current: 100 A
 pulse length: 1 ms
 pulse to pulse: ~ 3s (not very sensitive)
Summer Student Presentation
Kim Temming
16
Outlook
 continue measurement
 more different devices (to get statistics)
 more sensitive temperature control
 dependence on the readout temperature
 for fluences 1.0 E12...E15 p/cm2
 from –10 C to +30 C
 dependence on the fluence
 1.0 E12 p/cm2 up to 1.0 E15 p/cm2
 annealing of samples in oven
 40, 60. 80, 100 degree celsius
End
Summer Student Presentation
Kim Temming
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