Difference between revisions of "HRRL radiation footprint simulations"

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[[File:HRRL_Geom_12-24-09.jpg]]
 
[[File:HRRL_Geom_12-24-09.jpg]]
  
[http://wiki.iac.isu.edu/index.php/HRRL_room_dimensions[HRRL room dimension]]
+
[http://wiki.iac.isu.edu/index.php/HRRL_room_dimensions[HRRL room dimension measured by Jason Swanson]]
  
  
 
[http://wiki.iac.isu.edu/index.php/Positrons][[Positrons]]
 
[http://wiki.iac.isu.edu/index.php/Positrons][[Positrons]]

Revision as of 15:09, 19 December 2009

Design a simulation to determine radiation footprint in HRRL cell.


1.) The ceiling is 4 feet thick

2.) there is PB shiedling between the HRRL accelerator room and the accelerator operator station

3.) the dirt is about 10 feet thick on the wall side where the accelerator is going to be mounted

4.) determine shielding wall thickness for HRRL cavity to reduce dose out the door

5.) Determine shielding for Tungsten converter

Drawing

Get a drawing from facilities documenting the shielding in that cell with dimensions


Denton Dance: x4710, may be able to provide drawings. B119 Beam Lab

Material Definitions

Concrete

Concrete has 6 elements and a density of 2.7 g/cm^3

Element Atomic Weight (A) Atomic Number (Z) Proportion by Weight
1 1.0079 1. 0.004
2 15.9994 8. 0.509
3 26.981539 13 0.034
4 28.0855 14. 0.345
5 40.078 20 0.070
6 55.8474 28. 0.038

GEANT4 code


a = 1.0079*g/mole;
  G4Element* elH  = new G4Element(name="Hydrogen",symbol="H" , z= 1., a);
  a = 15.9994*g/mole;
  G4Element* elO  = new G4Element(name="Oxygen"  ,symbol="O" , z= 8., a);
a = 26.981539*g/mole;
  G4Element* elAl  = new G4Element(name="Aluminum",symbol="Al" , z= 13., a);
a = 28.0855*g/mole;
  G4Element* elSi  = new G4Element(name="Silicon",symbol="Si" , z= 14., a);
a = 40.078*g/mole;
  G4Element* elCa  = new G4Element(name="Calcium",symbol="Ca" , z= 20., a);
a = 55.8474*g/mole;
  G4Element* elNi  = new G4Element(name="Nickel",symbol="Ni" , z= 28., a);



  density =2.7*g/cm3;
  G4Material* Concrete = new G4Material(name="Concrete ",density,ncomponents=6);
  Concrete->AddElement(elH, fractionmass=0.4*perCent);
  Concrete->AddElement(elO, fractionmass=50.9*perCent);
 Concrete->AddElement(elAl, fractionmass=3.4*perCent);
 Concrete->AddElement(elSi, fractionmass=34.5*perCent);
 Concrete->AddElement(elCa, fractionmass=7.0*perCent);
 Concrete->AddElement(elNi, fractionmass=3.8*perCent);

Relative Rates

The first step in the simulation will be to compare relative radiation rates at the exit of the accelerator room. The radiation exiting the accelerator room before and after moving the accelerator will be simulated. Although all particles can be tracked we will mostly be interested in gamma and neutron fluxes through the door. The ratio of before/after moving fluxes for gamma and neutron should be plotted as a function of energy.

Geometry

File:HRRL Geom 12-24-09.jpg

[HRRL room dimension measured by Jason Swanson]


[1]Positrons