Neutron pinball

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The Simulation

Photons with a Bremsstrahlung energy distribution are incident upon 64 thorium cylindrical targets. All thorium targets have 1 cm center-to-center spacing, a dia. of 0.4 cm, and a height of 8 cm. The target geometry is shown in the neutron flux plot below. The targets are surrounded by a cylindrical room filled with air, which has a radius equal to the distance between the target and the detectors (150 cm), and a height equal to the vertical extent of the detectors (76 cm). Upon the creation of a neutron from photofission, its initial direction of travel is logged. Once the neutron exits the cylindrical room, its direction of travel as seen by a detector placed room's edge, is compared to it's initial direction of travel, giving a neutron deflection angle.

A uniform plane source of Bremsstrahlung photons, traveling from left to right, induce photofission in the targets. The rate of neutron production is represented by the color.

Results

12% of neutrons scattered in the thorium cylinders alone, and 14% scattered when air was included. The histogram below reveals that if a neutron did scatter, it most likely did so at an unacceptable angle. Neutrons that didn't undergo any interaction are not included in this plot.


Non-zero deflection angles of neutrons

Effect of room air

About 2% of neutrons were scattered in the air. Below is a histogram of neutron deflection angles when neutron-thorium interaction was turned off. Neutrons that didn't undergo any interaction are not included in this plot.

Non-zero deflection angles of neutrons by air

sdsd

The geometry shown below provides an unobstructed line of sight from every target, to the entire face of every detector. The cylindrical targets have a diameter of 2 mm. When using thorium as the target material, 3% of neutrons were deflected.

(A) The grey regions represent the line of sight from each target to the entire face of each detector. (B) Neutron line of sight from all targets to all detectors. (C) A close up reveals how this geometry provides an unobstructed line of sight from every target, to the entire face of every detector.

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