Proton Calorimetry/Experimental Runs/2017/September7: Difference between revisions

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Beam tests of the Nuvia 10 mm, 4 mm and 3 mm scintillator sheets with PRaVDA CMOS pixel sensors (PRIAPUS) at the Birmingham Cyclotron with a 28 MeV beam.
Beam tests of the Nuvia 10 mm, 4 mm and 3 mm scintillator sheets with PRaVDA CMOS pixel sensors (PRIAPUS) at the Birmingham Cyclotron with a 28 MeV beam.
__TOC__


== Pre-data Taking Information and Notes ==
== Pre-data Taking Information and Notes ==
Line 69: Line 71:
|| 28MeV_3mmscint_ABC_spread_10pA_1cmC
|| 28MeV_3mmscint_ABC_spread_10pA_1cmC
|-
|-
|Beam || 10 pA || 3 x 3 mm || ABC || Lights off this time! || 28MeV_3mmscint_ABC_spread_10pA_1cmC_2
|-
|Beam || 10 pA || 3 x 3 mm || ABC || Repeat measurement for reproducibility || 28MeV_3mmscint_ABC_spread_10pA_1cmC_3
|-
|Beam direction || N/A || N/A || N/A ||
*Measure the direction of the beam relative to the screen by shining a laser on the sensor to make sure we understand the Bragg Peak that we see
*Saturation of the sensor
|| Laser_beam_direction
|-
|Beam direction || N/A || N/A || N/A ||
*Cover some of the sensor not to saturate it
*Beam direction determined to be (for the top panel display):
<div align="center"> SCREEN <--- BEAM </div>
<div align="center"> (where the arrow represents the direction of the beam) </div>
|| Laser_beam_direction_cover
|-
|Beam || 10 pA || 4 mm and 3 mm || 3A 4A ||
*Alignment: 4A [gap] 3A <--- BEAM
*Lights were left on for this run. Data not useable!
|| 28MeV_3mmA_4mmA_spread_10pA_1cmC
|-
|Beam || 10 pA || 4 mm and 3 mm || 3A 4A || Lights off this time! || 28MeV_3mmA_4mmA_spread_10pA_1cmC_2
|-
|Beam || 10 pA || 4 mm and 3 mm || 3A 4A || Repeat measurement for reproducibility || 28MeV_3mmA_4mmA_spread_10pA_1cmC_3
|-
|Beam || 10 pA || 3 mm and 4 mm || 4A 3A ||
*Scintillator plates switched around
*Alignment" 3A [gap] 4A <--- BEAM
|| 28MeV_4mmA_3mmA_spread_10pA_1cmC
|-
|Beam || 20 pA || 3 mm and 4 mm || 4A 3A ||
*Continue with this configuration and increase current until we get to the maximum current that won't saturate the sensors
*First, double the current
|| 28MeV_4mmA_3mmA_spread_20pA_1cmC
|-
|Beam || 25 pA || 3 mm and 4 mm || 4A 3A ||
*Increase current to 25 pA
*Possible saturation of sensors
|| 28MeV_4mmA_3mmA_spread_25pA_1cmC
|-
|Beam || 20 pA || 3 x 3 mm || ABC ||
*The maximum current before saturation is ~ 20 pA
*Repeat tests with 3 scintillator plates at this current
*Alignment: 3C [gap] 3B [gap] 3A <--- BEAM
*Lights were left on for this run. Data not useable!
|| 28MeV_3mmscint_ABC_spread_20pA_1cmC
|-
|Beam || 20 pA || 3 x 3 mm || ABC ||
*Lights off this time!
*The file preview showed that there is a tilt observed in the resulting data. This was caused by scintillator A tilting to the right in real life, as show in the below picture, which was taken just after the data run was taken:
<div class="image400px" style="text-align: center;">
[http://www.hep.ucl.ac.uk/pbt/wikiData/images/Birmingham_sept2017/tilted_scintillators.jpg http://www.hep.ucl.ac.uk/pbt/wikiData/images/Birmingham_sept2017/tilted_scintillators.jpg]
<br />
</div>
|| 28MeV_3mmscint_ABC_spread_20pA_1cmC_2
|-
|Beam || 20 pA || 3 x 3 mm || BCA || Alignment: 3A [gap] 3C [gap] 3B <--- BEAM || 28MeV_3mmscint_BCA_spread_20mA_1cmC
|-
|Background || N/A || 3 x 3 mm || BCA || || Background_2
|-
|Beam || 20 pA || 3 x 3 mm || BCA ||
*Alignment: 3A [gap] 3C [gap] 3B <--- BEAM
*Blue tack used to keep scintillator plates straighter and test repeated with the same alignment.
*Lights were left on for this run. Data not useable!
|| 28MeV_3mmscint_BCA_spread_20mA_1cmC_2
|-
|Beam || 20 pA || 3 x 3 mm || BCA || Lights off this time! || 28MeV_3mmscint_BCA_spread_20mA_1cmC_3
|-
|Beam || 20 pA || 3 x 3 mm || CAB ||
*Alignment: 3B [gap] 3A [gap] 3C <--- BEAM!
*The tiles remained straighter for this run!
|| 28MeV_3mmscint_CAB_spread_20pA_1cmC
|-
|Beam || 20 pA || 3 mm and 4 mm || 4A 3A || Alignment: 3A 4A <--- BEAM || 28MeV_4mmA_3mmA_spread_20pA_1cmC
|-
|Beam || 20 pA || 3 mm and 4 mm || 4B 3A || Alignment: 3A 4B <--- BEAM || 28MeV_4mmB_3mmA_spread_20pA_1cmC
|-
|Beam || 20 pA || 1 x 10 mm || 10 A ||
*Data taking resumed after short lunch break (in case this is of any relevance to any change in data caused by the beam being switched off for a short while)
*Alignment: 10A <--- BEAM
|| 28MeV_10mmA_20pA_1cmC
|-
|Background || N/A || 1 x 10 mm || 10A || || Background_3
|-
|Beam || 20 pA || 1 x 10 mm || 10B || Alignment: 10B <--- BEAM || 28MeV_10mmB_20pA_1cmC
|-
|Beam || 10 pA || 1 x 10 mm || 10B || Decrease the current by a factor of 2 until we don't see anything above background || 28MeV_10mmB_10pA_1cmC
|-
|Beam || 5 pA || 1 x 10 mm || 10B || Current decreased by another factor of 2 || 28MeV_10mmB_5pA_1cmC
|-
|Beam || 2.5 pA || 1 x 10 mm || 10B || Current decreased by another factor of 2 || 28MeV_10mmB_2-5pA_1cmC
|-
|Beam || 1.25 pA || 1 x 10 mm || 10B || Current decreased by another factor of 2 || 28MeV_10mmB_1-25pA_1cmC
|-
|Beam || 20 pA || 1 x 10 mm || 10B ||
*Current brought back up to 20 pA
*10 repeats of 1 second frames recorded, with _1, _2 etc. appended to file name
*Current dropped off slightly during acquisition
|| 28MeV_10mmB_20pA_1cmC_repeat
|-
|Beam || 20 pA || 1 x 10 mm || 10B ||
*The setup has been moved off-centre to check for uniformity, with the beam hitting the right edge of the scintillator (when looking into the beam)
*The beam was also checked with a film placed on the scintillator to make sure the beam was hitting, and not missing, the scintillator
*10 repeats of 1 second frames recorded, with _1, _2 etc. appended to file name
|| 28MeV_10mmB_20pA_1cmC_right
|-
|Beam || 20 pA || 1 x 10 mm || 10B ||
*Plate 10B was removed from the stand and brought closer to the sensor to reduce the gap between the scintillator and the sensor to ~ 2mm at the bottom (and the gap slightly increasing towards the top, so the scintillator leans away from the sensor as it gets to the top of the sensor)
*Very saturated data!
|| 28MeV_10mmB_20pA_1mcC_close
|-
|Beam || 10 pA || 1 x 10 mm || 10B ||
*Reduce current by factor of 2
*Still see some slight saturation
|| 28MeV_10mmB_10pA_1mcC_close
|-
|Beam || 7 pA || 1 x 10 mm || 10 B ||
*Further reduce current
*No saturation seen
|| 28MeV_10mmB_7pA_1cmC_close
|-
|Beam || 7 pA || 3 x 3 mm || ABC ||
*3 scintillator plates brought close to the sensor, taped together for stability so therefore without any separation
*Alignment: 3C [gap] 3B [gap] 3A <--- BEAM
|| 28MeV_3mmscint_ABC_7pA_1mcC_close
|-
|Beam || 5 pA || 3 x 3 mm || ABC || Current dropped to 5 pA in hope of seeing more separation with less light || 28MeV_3mmscint_ABC_4pA_1mcC_close
|}
== Conclusions ==
*A very successful first test beam at Birmingham, where we could see the Bragg Peak when using two plates (3 mm and 4 mm):
<div class="image600px" style="text-align: center;">
[http://www.hep.ucl.ac.uk/pbt/wikiData/images/Birmingham_sept2017/4mmA_3mmA_spread_20pA.png http://www.hep.ucl.ac.uk/pbt/wikiData/images/Birmingham_sept2017/4mmA_3mmA_spread_20pA.png]
<br />
</div>
*Simulations were carried out of a 28 MeV proton energy and a 5 mm radius beam, with 10,000 events. The resulting energy deposited and the stopping distance can be seen below:
<div class="image600px" style="text-align: center;">
[http://www.hep.ucl.ac.uk/pbt/wikiData/images/Birmingham_sept2017/28MeV_4mmRadius.jpg http://www.hep.ucl.ac.uk/pbt/wikiData/images/Birmingham_sept2017/28MeV_4mmRadius.jpg]
<br />
</div>
The stopping distance is ~ 6.1 mm, according to simulations. This agrees with the test beam where the Bragg peak is seen as two points in two plates totalling up to a total of 7 mm of scintillator.
*Full data analysis still to be carried out!

Latest revision as of 15:56, 19 September 2017

Beam tests of the Nuvia 10 mm, 4 mm and 3 mm scintillator sheets with PRaVDA CMOS pixel sensors (PRIAPUS) at the Birmingham Cyclotron with a 28 MeV beam.

Pre-data Taking Information and Notes

  • The tests were carried out with an energy of 28 MeV (32 MeV was unavailable as the cyclotron had recently been through repairs). No Bragg Peak measurement was carried out to confirm the exact beam energy due to time restrictions.
  • The beam was run without a scattering foil. A 1 cm diameter uniform beam was achieved by placing a 1 cm collimator in the beam, with a beam scan onto film confirming the size. An ionisation chamber was placed upstream of the collimator to accurately monitor the current.
  • The dynamic range of the CMOS sensors is 14 bits. The electron conversion value from ADC is 50 electrons per ADC value. The measurements to establish this were carried out at the beginning of experimentation with the sensors and this value may have changed due to radiation damage etc.
  • From previous measurements, the average background value per pixel is ~ 700.
  • The data was recorded at 45 frames/second.
  • The scintillator stack was set up perpendicular to the proton beam, with the exposed sides of the scintillator facing the sensors:

setup_1.jpg setup_2.jpg

  • The scintillator stack was quite well aligned with the horizontal centre of the beam. We did our best to align the vertical centre of the scintillator stack with the beam as well, however as can be seen from the image below, where the black "line" shows the divide between and hence the centre of the sensors, the beam hit just below centre:

off_centre.jpg

  • The working directory on the PRIAPUS computer where the data is stored is:

idMateData\Bham070917\

  • The directory the data is stored at UCL in is:

/unix/pbt/data/birmingham/sept_2017

Data Taking

Type of run Current Scintillator sheets used Scintillator arrangement Notes File name
Background N/A 3 x 3 mm ABC
  • Background ADC count slightly higher than usual
  • Tiles are grouped together in a tight formation (until mentioned otherwise)

tight_scintillators.jpg

Background_1
Beam 1 nA 3 x 3 mm ABC Saturation of sensor, ADC values at 14,000 28MeV_3mmscint_ABC_1nA_1cmC
Beam 0.1 nA 3 x 3 mm ABC
  • Current reduced by a factor of 10
  • Beam dropped during run
 28MeV_3mmscint_ABC_100pA_1cmC_1
Beam 0.1 nA 3 x 3 mm ABC Saturation of sensor 28MeV_3mmscint_ABC_100pA_1cmC_2
Beam 10 pA 3 x 3 mm ABC Sensor no longer saturated, but no separation due to formation of tiles 28MeV_3mmscint_ABC_10pA_1cmC
Beam 10 pA 3 x 3 mm ABC
  • Due to gap between the sensor and the scintillators there is an overlap in the light collected by the sensor and no separation of the scintillators can be seen
  • In order to see some separation, place the scintillators with a gap of ~ 1-2 cm between each sheet

spread_out_scintillators.jpg

  • This setup remains in place until mentioned otherwise
  • Lights were left on for the first run. Data not useable!
 28MeV_3mmscint_ABC_spread_10pA_1cmC
Beam 10 pA 3 x 3 mm ABC Lights off this time! 28MeV_3mmscint_ABC_spread_10pA_1cmC_2
Beam 10 pA 3 x 3 mm ABC Repeat measurement for reproducibility 28MeV_3mmscint_ABC_spread_10pA_1cmC_3
Beam direction N/A N/A N/A
  • Measure the direction of the beam relative to the screen by shining a laser on the sensor to make sure we understand the Bragg Peak that we see
  • Saturation of the sensor
 Laser_beam_direction
Beam direction N/A N/A N/A
  • Cover some of the sensor not to saturate it
  • Beam direction determined to be (for the top panel display):
SCREEN <--- BEAM
(where the arrow represents the direction of the beam)
Laser_beam_direction_cover
Beam 10 pA 4 mm and 3 mm 3A 4A
  • Alignment: 4A [gap] 3A <--- BEAM
  • Lights were left on for this run. Data not useable!
 28MeV_3mmA_4mmA_spread_10pA_1cmC
Beam 10 pA 4 mm and 3 mm 3A 4A Lights off this time! 28MeV_3mmA_4mmA_spread_10pA_1cmC_2
Beam 10 pA 4 mm and 3 mm 3A 4A Repeat measurement for reproducibility 28MeV_3mmA_4mmA_spread_10pA_1cmC_3
Beam 10 pA 3 mm and 4 mm 4A 3A
  • Scintillator plates switched around
  • Alignment" 3A [gap] 4A <--- BEAM
 28MeV_4mmA_3mmA_spread_10pA_1cmC
Beam 20 pA 3 mm and 4 mm 4A 3A
  • Continue with this configuration and increase current until we get to the maximum current that won't saturate the sensors
  • First, double the current
 28MeV_4mmA_3mmA_spread_20pA_1cmC
Beam 25 pA 3 mm and 4 mm 4A 3A
  • Increase current to 25 pA
  • Possible saturation of sensors
 28MeV_4mmA_3mmA_spread_25pA_1cmC
Beam 20 pA 3 x 3 mm ABC
  • The maximum current before saturation is ~ 20 pA
  • Repeat tests with 3 scintillator plates at this current
  • Alignment: 3C [gap] 3B [gap] 3A <--- BEAM
  • Lights were left on for this run. Data not useable!
 28MeV_3mmscint_ABC_spread_20pA_1cmC
Beam 20 pA 3 x 3 mm ABC
  • Lights off this time!
  • The file preview showed that there is a tilt observed in the resulting data. This was caused by scintillator A tilting to the right in real life, as show in the below picture, which was taken just after the data run was taken:

tilted_scintillators.jpg

28MeV_3mmscint_ABC_spread_20pA_1cmC_2
Beam 20 pA 3 x 3 mm BCA Alignment: 3A [gap] 3C [gap] 3B <--- BEAM 28MeV_3mmscint_BCA_spread_20mA_1cmC
Background N/A 3 x 3 mm BCA Background_2
Beam 20 pA 3 x 3 mm BCA
  • Alignment: 3A [gap] 3C [gap] 3B <--- BEAM
  • Blue tack used to keep scintillator plates straighter and test repeated with the same alignment.
  • Lights were left on for this run. Data not useable!
 28MeV_3mmscint_BCA_spread_20mA_1cmC_2
Beam 20 pA 3 x 3 mm BCA Lights off this time! 28MeV_3mmscint_BCA_spread_20mA_1cmC_3
Beam 20 pA 3 x 3 mm CAB
  • Alignment: 3B [gap] 3A [gap] 3C <--- BEAM!
  • The tiles remained straighter for this run!
 28MeV_3mmscint_CAB_spread_20pA_1cmC
Beam 20 pA 3 mm and 4 mm 4A 3A Alignment: 3A 4A <--- BEAM 28MeV_4mmA_3mmA_spread_20pA_1cmC
Beam 20 pA 3 mm and 4 mm 4B 3A Alignment: 3A 4B <--- BEAM 28MeV_4mmB_3mmA_spread_20pA_1cmC
Beam 20 pA 1 x 10 mm 10 A
  • Data taking resumed after short lunch break (in case this is of any relevance to any change in data caused by the beam being switched off for a short while)
  • Alignment: 10A <--- BEAM
 28MeV_10mmA_20pA_1cmC
Background N/A 1 x 10 mm 10A Background_3
Beam 20 pA 1 x 10 mm 10B Alignment: 10B <--- BEAM 28MeV_10mmB_20pA_1cmC
Beam 10 pA 1 x 10 mm 10B Decrease the current by a factor of 2 until we don't see anything above background 28MeV_10mmB_10pA_1cmC
Beam 5 pA 1 x 10 mm 10B Current decreased by another factor of 2 28MeV_10mmB_5pA_1cmC
Beam 2.5 pA 1 x 10 mm 10B Current decreased by another factor of 2 28MeV_10mmB_2-5pA_1cmC
Beam 1.25 pA 1 x 10 mm 10B Current decreased by another factor of 2 28MeV_10mmB_1-25pA_1cmC
Beam 20 pA 1 x 10 mm 10B
  • Current brought back up to 20 pA
  • 10 repeats of 1 second frames recorded, with _1, _2 etc. appended to file name
  • Current dropped off slightly during acquisition
 28MeV_10mmB_20pA_1cmC_repeat
Beam 20 pA 1 x 10 mm 10B
  • The setup has been moved off-centre to check for uniformity, with the beam hitting the right edge of the scintillator (when looking into the beam)
  • The beam was also checked with a film placed on the scintillator to make sure the beam was hitting, and not missing, the scintillator
  • 10 repeats of 1 second frames recorded, with _1, _2 etc. appended to file name
 28MeV_10mmB_20pA_1cmC_right
Beam 20 pA 1 x 10 mm 10B
  • Plate 10B was removed from the stand and brought closer to the sensor to reduce the gap between the scintillator and the sensor to ~ 2mm at the bottom (and the gap slightly increasing towards the top, so the scintillator leans away from the sensor as it gets to the top of the sensor)
  • Very saturated data!
 28MeV_10mmB_20pA_1mcC_close
Beam 10 pA 1 x 10 mm 10B
  • Reduce current by factor of 2
  • Still see some slight saturation
 28MeV_10mmB_10pA_1mcC_close
Beam 7 pA 1 x 10 mm 10 B
  • Further reduce current
  • No saturation seen
 28MeV_10mmB_7pA_1cmC_close
Beam 7 pA 3 x 3 mm ABC
  • 3 scintillator plates brought close to the sensor, taped together for stability so therefore without any separation
  • Alignment: 3C [gap] 3B [gap] 3A <--- BEAM
 28MeV_3mmscint_ABC_7pA_1mcC_close
Beam 5 pA 3 x 3 mm ABC Current dropped to 5 pA in hope of seeing more separation with less light 28MeV_3mmscint_ABC_4pA_1mcC_close

Conclusions

  • A very successful first test beam at Birmingham, where we could see the Bragg Peak when using two plates (3 mm and 4 mm):

4mmA_3mmA_spread_20pA.png

  • Simulations were carried out of a 28 MeV proton energy and a 5 mm radius beam, with 10,000 events. The resulting energy deposited and the stopping distance can be seen below:

28MeV_4mmRadius.jpg

The stopping distance is ~ 6.1 mm, according to simulations. This agrees with the test beam where the Bragg peak is seen as two points in two plates totalling up to a total of 7 mm of scintillator.

  • Full data analysis still to be carried out!
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