Difference between revisions of "JB Absolute theta"

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[[Production Analysis|go_back]]
 
[[Production Analysis|go_back]]
  
== Overview==
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[[JB Absolute theta(oldmethod)]]
Here I use neutron single events to measure the distribution of theta_abs, or the angle between an incident photon and a resultaning photo-neutron.
 
The distribution of uncorrelated neutrons from the SF of californium 252 is used to "divide out" the effects of detector geometry, efficiency, drifts, ect.
 
For D2O, the result is compared to an MCNP simulation which was built to model as many aspects of the experiment as possible.
 
  
== Simulation ==
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=Analysis=
I performed an MCNP simulation with a D2O target (axis length = 2"; dia. = 0.75")  subject to a 10.5 MeV end-point bremsstrahlung beam.  A mock-up of the entire neutron detector array is included in the simulation. Detector physics is modeled by applying a detection threshold in terms of light output (MeVee), which is equal to the typical MeVee produced by 0.5 MeV neutrons within the scintillator.
 
  
A Cf252 source was also simulated, allowing me to apply the exact same analysis technique to simulation and experimental data .
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After my first attempt at reconstructing  the theta_abs distribution gave mediocre results, I decided to try again, but this time without integrating over experimental observables throught analysis, except for at the final step. To illustrate what I mean, see the histogram below:
  
The plot below shows the relative distribution of neutron direction cosines w.r.t. the incident photon beam. These neutrons are not effected by scattering or detector geometry, since the direction cosine are taken right as neutrons are created.  
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[[File:D2O3DHistogram.png|700px|thumb|center|alt=Large | Every singles event lies in a three dimensional space consisting of a PMT top and bottom time, and a specific detector. These observables can be recast as energy, vertical z position, and detector angle (54,78,102, ect). ]]
  
[[File:MCNPSimD20Theta abs.png|650px]]
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The benefit of conducting the analysis in this 3D space, is that the neutrons correlated with the beam can be normalized to uncorrelated Cf252 neutrons detected in the same detector with similar positions and energies.
 
 
== Analysis  ==
 
Ten detectors are used in the measurement, 5 beam left and 5 beam right. For each detector on beam left, there is a corresponding detector on beam right which covers the same range in theta_abs. Each left-right pair of detectors produces a peak in the theta_abs distribution, seen below.
 
 
 
[[File:NCorrTheta abs histogram.png||350px]]
 
 
 
During the analysis, each peak is condensed into a single point whose value on the y-axis is the mean of the peak, and is the weighted average, or "center of mass",  along the x-axis.
 
 
 
==Final results ==
 
 
 
== MCNP-POLIMI ==
 
 
 
Below is an MCNP-POLIMI simulation of a cylindrical D20 target (axis length = 2"; dia. = 0.75") subject to a bremsstrahlung photon beam with an end point of 10.5MeV.  The plot below shows the relative distribution of neutron direction cosines w.r.t. the incident photon beam. All neutrons are from the photodisintegration of D20 and the direction cosine is taken as neutrons exit the target geometry.
 
 
 
[[File:MCNPSimD20Theta abs.png|650px]]
 

Latest revision as of 21:28, 22 November 2017

go_back

JB Absolute theta(oldmethod)

Analysis

After my first attempt at reconstructing the theta_abs distribution gave mediocre results, I decided to try again, but this time without integrating over experimental observables throught analysis, except for at the final step. To illustrate what I mean, see the histogram below:

Large
Every singles event lies in a three dimensional space consisting of a PMT top and bottom time, and a specific detector. These observables can be recast as energy, vertical z position, and detector angle (54,78,102, ect).

The benefit of conducting the analysis in this 3D space, is that the neutrons correlated with the beam can be normalized to uncorrelated Cf252 neutrons detected in the same detector with similar positions and energies.