LB January Flux Simulations

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Revision as of 18:03, 25 January 2018 by Brenleyt (talk | contribs)
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Simulations were run using geant4 to try and see if the ratio of the flux between the nickel foil and the inner selenium pellet would explain why the ratios of the rates are not correct. A general particle source was used to fire electrons in a beam at a titanium beam window, which then proceeds to an aluminum/tungsten radiator. After that the particles will encounter a nickel foil followed by an aluminum sheet and finally a selenium pellet that is -0.75cm off of the beam axis (to try and replicate the location of the foil relative to the selenium pellet). The run.mac file is shown below

/gps/particle e-

/gps/position 0 0 -5 m

/gps/pos/type Plane

/gps/pos/shape Circle

/gps/pos/radius 0.5 cm

/tracking/verbose 2

/gps/direction 0 0 1

/gps/verbose 2

/gps/pos/sigma_r 0.5 cm

/gps/energy 32 MeV

/run/beamOn 50000

The dimensions of the pieces of interest are:

Se Pellet: 0.25cm radius Nickel Foil: 6cm in x, 2cm in y

A picture of the setup is shown below:

LB JanFluxSim SideView.png LB JanFluxSim RotatedView.png

Below are the flux plots as a function of position for the nickel foil and the selenium pellet using a 2.5cm beam diameter.

LB NickelFlux G4Sim FullView Jan2018.png LB SeFlux G4Sim FullView Jan2018.png

Now try moving the target around until there is an area that has twice as much flux as the selenium pellet.

LB NickelFlux G4Sim Jan2018.png LB SeFlux G4Sim Jan2018.png


We can see here that the selenium pellet has 13620 counts in it, while the selected region of the nickel foil has 26980 counts. Taking the ratio gives 0.50.

If we are looking for a bin that is the size of the target that has twice the amount of counts, then that was not found with this beam diameter, so I will try smaller diameter beams as well.


For a 1.5cm diameter beam I was able to find a place on the nickel foil that had half as much flux as the selenium. Below is a plot of the selenium flux

LB SeFluxPlot FullView 1.5cmBeam Jan2018.png

It can be seen that this is a 10mmx10mm square. So find a 10mmx10mm square on the nickel foil that has half as much flux as seen by the selenium. Below is a plot of that region.

LB NickelFlux 1.5cmBeam Zoom Jan2018.png

Note that this position on the nickel foil is still at the bottom of the Aluminum cylinder, similar to where the selenium would actually be due to the fact that there was not much ash in the cylinder to raise its position in y. It would seem that if the selenium pellet were centered off the x axis by 5mm, then it would be feasible that the flux through the selenium pellet would be half.