Difference between revisions of "Niowave 9-2015"

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Progress Report, September 2015
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Niowave Positron Project Progress for September 2015
  
  
Simulations were performed to predict the efficiency of producing positrons using a Lead-Bismuth target and a 10 MeV incident electron.  MCNPX and GEANT4 were used to predict this efficiency in an effort to benchmark the results.  Niowave performed a simulation using MCNPX and ISU used GEANT4.  A comparison of the positron production efficiency predictions made by MCNPX and G4beamline (GEANT4) indicates that they were consistent.
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Simulations were performed to predict the efficiency of producing positrons using a Lead-Bismuth target and a 10 MeV incident electron.  MCNPX and GEANT4 were used to predict this efficiency in an effort to benchmark the results.  Niowave performed a simulation using MCNPX and ISU used GEANT4.  A comparison of the positron production efficiency predictions made by MCNPX and G4beamline (GEANT4) is shown in the table below.  The two simulation packages appear to be consistent with each other for some thicknesses.
  
  
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The spatial distributions observed appear below
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Below are the momentum distributions observed for both electrons and electrons using MCNPX.  The 10 MeV electrons loose a mean energy of about 3 MeV traversing the 2mm thick PbBi target.  The incident 10 MeV electrons produce Brehsstrahlung photons as traverse the PbBi target.  These photon will produce electron-positron pairs within the PbBi target material.  The positrons below escape the PbBi target and have a momentum between one and two MeV.
  
Electrons and Positrons after 2mm of LBE:
 
  
 
Electrons:
 
Electrons:

Latest revision as of 14:39, 13 April 2016

Niowave Positron Project Progress for September 2015


Simulations were performed to predict the efficiency of producing positrons using a Lead-Bismuth target and a 10 MeV incident electron. MCNPX and GEANT4 were used to predict this efficiency in an effort to benchmark the results. Niowave performed a simulation using MCNPX and ISU used GEANT4. A comparison of the positron production efficiency predictions made by MCNPX and G4beamline (GEANT4) is shown in the table below. The two simulation packages appear to be consistent with each other for some thicknesses.


PbBi Thickness (mm) #positrons/million electrons (G4Beamline) #positrons/million electrons (MCNPX)
1 1138,1154,1097,1159,1125 =1135[math]\pm[/math]25 1091
1.5 1668,1701,1639, 1644, 1628=1656[math]\pm[/math]29 1728
2 1937,1930,1851,1874,1945=1907[math]\pm[/math]42 1984
3 1889,1821,1852,1809,1859=1846[math]\pm[/math]32 1986
4 1726,1696,1673,1693,1681=1694[math]\pm[/math] 20 1858
5 1566,1543,1546,1625,1566=1569[math]\pm[/math]33 1646
6 1549, 1486,1564,1545,1452=1520[math]\pm[/math] 50 1541
7 1462,1327, 1407,1489 ,1477=1432[math]\pm[/math] 67 1541
8 1289, 1335,1280, 1271, 1280 = 1291[math]\pm[/math] 25
10 1141,1241, 1199, 1202, 1148 =1186[math]\pm[/math]42 1216


Below are the momentum distributions observed for both electrons and electrons using MCNPX. The 10 MeV electrons loose a mean energy of about 3 MeV traversing the 2mm thick PbBi target. The incident 10 MeV electrons produce Brehsstrahlung photons as traverse the PbBi target. These photon will produce electron-positron pairs within the PbBi target material. The positrons below escape the PbBi target and have a momentum between one and two MeV.


Electrons:

E01.pngE02.png

Positrons:

P01.pngP02.png