Pb Cylinder (AKA "Temp Shield")
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Creating Lead Cylinder
For a lead cylinder with outer radius of 60mm, to ensure Moller electrons can clear the material:
Since the Geant4 solid is based on it's half-distance with respect to the origin, we need to add 6000 to this to find the starting distance.
Geometry files follow the format:
Name: No Spaces Mother: root if primary component Description: Short explaination Position: The center of the object wrt to the vertex Rotation:0*deg 0*deg 0*deg Type: G4 Tube Dimensions: Inner Radius, Outer Radius, Half-Length in z, starting phi position angle of segment ,delta phi angle of segment Material: Defined in materials file Color:The color entry is a 6 digit hexadecimal number that represents Red, Green and Blue weights from 0 to 255 each in the form: RRGGBB Visible: 1=Yes, 0=No Style:1=Solid,0=Wireframe
Geometry File
File:PbCylinder geometry basic.txt
Material File
File:PbCylinder materials basic.txt
Modified gcard line
<detector name="/home/lds/src/CLAS/GEMC/clas12Tags/4a.2.2/experiments/clas12/PbCylinder/PbCylinder" factory="TEXT" variation="basic"/>
Gemc Visual
Trial Run
~/src/CLAS/GEMC/clas12Tags/4a.2.2/source/gemc -USE_GUI=1 -BEAM_P="e-, 11.0*GeV, 5.0*deg, 10*deg" -BEAM_V="(0, 0, 0)cm" -N=1 eg12.gcard
No Solenoid, No/0 Torus
No Solenoid, 0 Torus
1 Sol, 0 Tor
Modified Rates
Compare With/Without TEMP shield
Solenoid Field | With Temp Shield | Without Temp Shield | ||
---|---|---|---|---|
Vacuum | Air | Vacuum | Air | |
No Sol | C | D | E | F |
0.5 Sol | C | D | E | F |
1.0 Sol | C | D | E | F |