Difference between revisions of "CrossTalk"

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=Detector physics=
 
=Detector physics=
The detector physics used in the simulation is MCNP-POLIMI's default treatment for plastic organic scintillators. POLIMI uses electron equivalent light output (MeVee) for simulating  detector response. Assuming the detectors have a energy deposition threshold of 0.2 MeV, the corresponding threshold, in electron equivalent light output, becomes 0.03 MeVee.
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The detector physics used in the simulation is MCNP-POLIMI's default treatment for plastic organic scintillators. POLIMI uses electron equivalent light output (MeVee) for simulating  detector response. Assuming the detectors have a energy deposition threshold of 0.2 MeV, the corresponding threshold, in electron equivalent light output is 0.03 MeVee.
  
 
==Summary==
 
==Summary==
Neutron energy deposition from collisions with hydrogen and carbon are converted to electron equivalent light output (MeVee) by MCNP-POLIMI. Neutron collisions that all occur within a pulse collection time of 10 ns of each other are converted to MeVee and cumulated. If the cumulative light output exceeds 0.03 MeVee then it is considered a detection. The value 0.03 MeVee was chosen because it corresponds to a mean neutron energy deposit of 0.2 MeV.
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Neutron energy deposition from collisions with both hydrogen and carbon are converted to electron equivalent light output (MeVee) by MCNP-POLIMI. All neutron collisions that occur within the pulse collection time window (10 ns ) of eon another are converted to MeVee and summed. If the cumulative light output over the pulse collection time window  exceeds 0.03 MeVee, then a detection is registered. The value 0.03 MeVee was chosen because it corresponds to a mean neutron energy deposit of 0.2 MeV.
  
 
==Detector response==
 
==Detector response==

Revision as of 01:47, 19 July 2016

Go back MCNP simulations

Geometry

An array of 6 detectors are placed radially at a distance of 1 meter from an uncorrelated 252-CF source. The image below shows a top down view of the simulation geometry. The detector setups have a vertical extent of 30".

GeomEdited.png

Detector physics

The detector physics used in the simulation is MCNP-POLIMI's default treatment for plastic organic scintillators. POLIMI uses electron equivalent light output (MeVee) for simulating detector response. Assuming the detectors have a energy deposition threshold of 0.2 MeV, the corresponding threshold, in electron equivalent light output is 0.03 MeVee.

Summary

Neutron energy deposition from collisions with both hydrogen and carbon are converted to electron equivalent light output (MeVee) by MCNP-POLIMI. All neutron collisions that occur within the pulse collection time window (10 ns ) of eon another are converted to MeVee and summed. If the cumulative light output over the pulse collection time window exceeds 0.03 MeVee, then a detection is registered. The value 0.03 MeVee was chosen because it corresponds to a mean neutron energy deposit of 0.2 MeV.

Detector response

The electron equivalent (MeVee) conversion functions for neutrons were measured for plastic (BC 420) scintillators as a function of neutron energy deposit, [math]E_{n}[/math]. For deposit on hydrogen the measurements fit the following quadratic function:

[math]L=0.036E_{n}^{2}+0.125E_{n}[/math]

and for deposit on carbon:


[math]\displaystyle L=0.02E_{n}[/math]

Statistics

n-n correlation was not simulated. Source particles were emitted isotropically, one at a time. An estimation of the uncorrelated n-n coincidence rate provides a quantity that can be meaningfully compared against the simulated crosstalk rate. This rate can be described as the rate of measured n-n events if the fission neutrons were emitted isotropically and totally uncorrelated from one another. The uncorrelated n-n rate, [math]R_{nn}[/math], is estimated from the simulation as follows:

[math]R_{nn}=f*\nu(\nu-1)*N(N-1)*P_{d}^{2}[/math]

[math]f[/math] is the fission rate,
[math]\nu[/math] mean neutron multiplicity,
[math]N[/math] in the number of detectors, and
[math]P_{d}[/math] is the probability that a single neutron registers a hit in a single given detector. This value can be calculated directly from the simulation: [math]P_{d}=\frac{\text{total number of single hits}}{N*(\text{total number of src neutrons})}[/math]


The crosstalk rate, [math]R_{X}[/math], simply scales proportionally with neutron multiplicity, fission rate, and the number of detectors. The estimated crosstalk rate is given by:

[math]\displaystyle R_{X}=f*\nu*N*P_{X}[/math]

where [math]P_{X}[/math] is the probability of crosstalk per source neutron, which is calculated directly from the simulation result:

[math]P_{X}=\frac{\text{total number of cross talk events}}{\text{total number of src neutrons}}[/math]


In order to quantify the amount of crosstalk contamination, I define a 'signal-to-noise ratio' equal to the ratio between the estimated signal and crosstalk rates.

[math]SNR=\frac{R_{nn}}{R_X}=\frac{(\nu-1)*(N-1)*P_{d}^{2}}{P_{X}}[/math]

I'm uncertain about the exact value for neutron multiplicity, so I will assume it's equal to 2, since this value is reasonable and serves as a worst case scenario. Go back MCNP simulations