Bubble Chamber Beam Test September 2015

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Bubble Chamber Turn On

  • Fill with natural N2O – test bubble chamber systems operation


  • With beam on bubble chamber radiator:
  1. How does CCD camera perform under beam-on conditions?
  2. Count rates on bubble chamber. Do we get single or multiple bubbles from Bremsstrahlung beam exposure?
  3. Measure gamma ray beam spatial profile as reflected by bubble distribution. Is collimator effective in defining the gamma-ray beam?
  4. Test the bubble chamber laser shutter (gumby shutter)


  • Background measurements:
  1. Measure beam off environmental background in chamber-injector area
  2. Measure beam on background by looking outside fiducial volume
  3. Measure background with beam to Faraday Cup in CEBAF beamline (about two meters from chamber)
  4. Measure neutron events in chamber. Neutron radiation detectors in injector region will indicate if any neutrons are generated (especially at beam kinetic energies higher than 8.5 MeV).



Bubble Chamber Beam Test

  • Chamber is filled with natural N2O


  • Cross sections:

The cross sections are shown in the following figure:

CrossSections.gif


  • Expected rates:

The expected rates are calculated with 3 cm cell thickness and Bremsstrahlung beam from copper radiator.


  • The expected rates are shown in the following figure:

GNaturalN2O.gif


  • The expected rates with the latest data are shown in the following figure:

GNaturalN2OData.gif


  • The expected rates from oxygen isotopes are shown in the following figure:

GNaturalO.gif


  • 17O(γ,n)16O cross section:

Cs17Ogn new.gif


  • The expected rate from 17O(γ,n)16O is shown in the following figure:

G17On rate.gif


  • The expected rate from 17O(γ,n)16O with ThrCut = 130 keV is shown in the following figure:

G17On rate ThrCut.gif





Run Plan:


  • Check if Bubble Chamber is working properly:
  1. Start with K.E. of 7.7 MeV
  2. Determine the initial operational pressure and temperature
  3. Measure bubble rate. The expected rate is 1 bubble per sec at 10 µA
  4. Measure rate vs beam current (0.01, 0.1 and 1.0 µA)
  5. Measure the number of bubbles for 30 minutes per beam current


  • Suppression of 14N(γ,p)13C events:
  1. Start with beam at K.E. 7.0 MeV
  2. Increase beam K.E. by 0.2 MeV steps all the way to 8.6 MeV
  3. Adjust beam current to maintain a bubble rate of few per minute
  4. Measure the number of bubbles for 30 minutes per energy
  5. Reproduce the overall rate shown above
  6. At K.E. of 8.6 MeV, increase the chamber threshold by increasing the pressure. Suppress the 14N(γ,p)13C events.
  7. Once 14N(γ,p)13C is suppressed, the rate should drop by three orders of magnitude


  • Measuring rates from 18O(γ,α)14C:
  1. Now the chamber is at the new pressure
  2. Start with beam at K.E. 7.2 MeV
  3. Increase beam K.E. by 0.2 MeV steps all the way to 9.2 MeV
  4. Adjust beam current to maintain a bubble rate of few per minute
  5. Measure the number of bubbles for 30 minutes per energy
  6. Reproduce the overall rate from oxygen isotopes shown above
  7. Note the change in slope of rates vs. beam K.E. and the sharp kink around 7.6 MeV


  • Measuring 18O(γ,α)14C cross section:
  1. Start with beam at K.E. 7.4 MeV
  2. Increase beam K.E. by 0.1 MeV steps all the way to 8.4 MeV
  3. Adjust beam current to maintain a bubble rate of few per minute
  4. Perform Penfold-Leiss unfolding


Beam Kinetic Energy (MeV) Beam Current (µA) Time (hour)
7.4 10 10
7.5 10 10
7.6 10 5
7.7 2 5
7.8 2 5
7.9 1 5
8.0 1 5
8.1 0.8 5
8.2 0.4 5
8.3 0.2 5
8.4 0.2 5


The expected yield (counts) is shown in the following figure:

CsO18 Yield Brem bg.gif


The Penfold-Leiss unfolded cross section is shown in the following figure:

CsO18 Brem Unfold bg.gif



Analysis Files

  • Presentations
  • Filling Chamber with nitrous oxide: Movie [1]


  • Beam Current:

The following command dumps the archived current readback (-A) from Keithley Picoammeter K6485 to a file:

mySampler -b "2015-09-10 18:00:00" -s 1s -n 14400 IFY5D04K6485dataRead > BubbleCur_Sept10.txt
  • Data file of beam current on Bubble Chamber Faraday Cup or Radiator/Dump (September 10, 18:00 - 22:00): media:BubbleCur_Sept10.txt


The following command dumps the archived current readback from BCM0L02 Gigatronics (µA) to a file:

mySampler -b "2015-09-15 15:00:00" -s 1s -n 18000 IBC0L02Current > BubbleCur_Sept15.txt


  • Beam Energy:

The following command dumps the archived data relevant to measuring beam energy to a file:

mySampler -b "2015-09-10 18:00:00" -s 100s -n 6912 R027GSET R027GMES R027PSET R027PMES R028GSET R028GMES R028PSET R028PMES MDL0L02.BDL MDL0L02M > BubbleEne_Sept2015.txt



Logbook: List of Runs

A copy of the paper logbook: media:Bubble_Chamber_Sept_2015_Runs_List.pdf



Things To Do Next

No Beam Checklist

  • Survey and align 5D line


Beam Checklist

  • Calibrate 0L02 BCM
  • Quad-center 0L02, 0L02A, 5D00, 5D01 and set BPM SOFs accordingly
  • Measure beam position directly after radiator