Difference between revisions of "G4Beamline PbBi"

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Development of a Positron source using a PbBi converter and a Solenoid
 
Development of a Positron source using a PbBi converter and a Solenoid
  
=Task List=
+
=Conclusions=
 +
 
 +
#A 0.3 (0.6)  Tesla Solenoid with a diameter to allow a 9.74 (3.94) cm diameter pipe would collect a positron per thousand incident electrons on a 2mm thick LBE target with 0.25 mm thick SS windows.
 +
# A 15 cm long, 0.2 Tesla solenoid with a 3.94 diameter beam pipe would collect a positron per two thousand electrons impinging a 2mm thick LBE target with 0.25 mm thick SS windows.
 +
#A 4 Tesla Solenoid will remove beam pipe heating from scattered electrons downstream of the target when using a 3.94 cm diameter beam pipe.
 +
 
 +
=Reports=
 +
 
 +
[[Niowave_Report_11-30-2015]]
 +
 
 +
 
 +
deadline 4/12/16
  
1.) new electron and positron files for the case of two 0.25 mm thick SS windows around the PbBi target.
 
  
2.) Determine electron energy deposition in SS pipe per cm^2 of pipe surface area for pipes with a radius of 34.8, 47.5, 60.2, 72.9, and 97.4 mm and thickness of 5mm along the z-axis.
+
==[[Niowave_9-2015]]==
 +
==[[Niowave_10-2015]]==
 +
==[[Niowave_11-2015]]==
 +
==[[Niowave_12-2015]]==
 +
==[[Niowave_1-2016]]==
 +
==[[Niowave_2-2016]]==
 +
==[[Niowave_3-2016]]==
 +
==[[Niowave_4-2016]]==
 +
==[[Niowave_5-2016]]==
 +
==[[Niowave_6-2016]]==
  
3.) Insert uniform B-field that can be scaled from 0 to 0.3 and 1 Telsa.
+
=Task List=
 +
 
 +
0.) 34.8 mm pipe, 0.0 -> 0.5 Tesla, E= 6,8,10 MeV.
  
=Beam Pipe Heating=
 
  
 +
1.)  Create a positron (10,000 positrons) and electron event file containing t,x,y,z,Px,Py,Pz  for positrons exiting the solenoid and an incident Gaussian beam 1cm in diameter and with a sigma of 1cm.
  
A 10 MeV electron beam with a radius of 0.5 cm was incident on a 2 mm thick PbBi target.  The target is positioned at Z = -901 mm.  The plot below shows the energy deposited in MeV along the pipe.  The Z axis is along the beam direction.  The distance around the beam pipe is determine by taking the pipe radius (34.8 mm) and multiplying it by the Phi angle around the pipe.  The bins are 1cm x 1cm.
+
compare distributions with and without solenoid.
  
[[File:BeamPipeDepEPhi_34.8_082815.png |200px]][[File:BeamPipeDepE_34.8_082815.png| 200 px]]
+
2.) Determine the back ground when using a 3.48 diameter beam pipe and Solenoid field of 0.2  for a NaI detector placed at
  
About 450,000 MeV/cm^2 is deposited when 20 Million , 10 MeV electrons are incident on a 2 mm thick PbBi target.
+
3.) Experiment, install dipole and solenoid in the tunnel.
  
 +
=Beam Pipe Heating=
  
Beam Power = E(MeV) <math> \cdot </math>I (<math>\mu</math> A) = 10 MeV <math>\times</math> 1000 mA = 10 kW
+
[[PbBi_BeamPipeHeatin_2015]]
  
If all of the beam power goes into a 150 cm long beam pipe with a radius of 3.38 cm then the power deposited per area would be
+
=Converter target properties=
  
:<math>10000 \mbox{W} \times \frac{1}{150 \mbox{cm}} \times {\frac}{2 \pi \times 3.48 \mbox {cm} } = 3 \frac{\mbox{W}}{\mbox{cm}^2}</math>
 
  
Projections onto the Z-axis
+
[[PbBi_NioWave_TargetProperties_2015]]
  
[[File:BeamPipeDepE_34.8mmA_082815.png| 200 px]][[File:BeamPipeDepE_34.8mmB_082815.png| 200 px]]
 
  
To convert the above histogram to deposited power you would divide by the number of incident electrons, divide by the circumference of the beam pip, multiple the beam current, and use a unit conversion from MeV to W-s per MeV.
+
=Target thickness optimization=
  
<math>\left(125 \times 10^3 \frac{\mbox{MeV}}{\mbox{cm}}\right) \times \left( \frac{1}{2 \times 10^{7} \mbox{e}^-}  \right ) \times \left( \frac{1}{2 \times \pi \times 3.48 \mbox{cm}} \right )  \times  \left( \frac{1. \times 10^{-3}\mbox{ C}}{\mbox{s} }\right )\times \left( \frac{\mbox{e}^- }{1.6 \times 10^{-19}\mbox{ C}}\right ) \left( \frac{1.6 \times 10^{-13}\mbox{W} \cdot \mbox{ s}}{\mbox{MeV} }\right )  \times </math>
+
==[[PbBi_THickness_CylinderBeam]]==
  
: <math>= 0.29 \frac{W}{cm^2}</math>
+
==[[PbBi_THickness_GaussBeam]]==
  
 +
== [[PbBi_THickness_PntSource]]==
  
Below is energy deposited contributions from from photons(AVSzWg), positrons (AVSzWpos), and electrons.
+
=Solenoid=
  
 +
==Uniform ideal Solenoid==
  
[[File:BeamPipeDepE_34.8_082815_parttype.png | 200 px]]
+
=== [[PbBi_BeamPipeHeating_w_Solenoid_2015]]===
  
Why is the positron hotspot upstream of the target?
+
===[[PbBi_60cmLong_Solenoid_Collection_Efficiency_2015]]===
  
 +
==Positron & Electron event files==
  
 +
[[PbBi_PosEventFiles_VaccumGaps_2015]]
  
 +
[[PbBi_PosEventFiles_NoGaps_2016]]
  
 +
==Solenoid Map==
  
root commands used
+
Inner Radiusu=
  
TH2D *AVSz=new TH2D("AVSz","AVSz",100,-1000,0,12,-60,60)
+
Outer Radius =
BeamPipeE->Draw("35.*atan(PosYmm/PosXmm):PosZmm>>AVSz","DepEmeV");
 
AVSz->Draw("colz");
 
  
 +
Length =
  
 +
Current=
  
[[BeamPipeHeating_4mmthick_PbBi_PositronTarget]]
+
Magnetic Field Map in cylindrical coordinates (Z & R) from Niowave
  
==Unit conversion==
+
=Rear Window Thickness=
  
The energy deposited by photon, electrons, and positrons is predicted by GEANT4 and recorded in energy units of keV per incident electron on the PbBi target.  To convert this deposited energy to a power you need to assume a beam current.  Assuming 1 beam current of 1 mA, the conversion is given easily as
 
  
<math>\left( \frac{\mbox{keV}}{\mbox{cm}^2 \mbox{e}^-}\right) \times \left( \frac{ \mbox{e}^-}{1.6 \times 10^{-19}\mbox{C}} \right ) \times \left( \frac{1 \times 10^{-3} \mbox{C}}{\mbox{s}} \right )  \times \left( \frac{1.6 \times 10^{-16}\mbox{W} \cdot \mbox{ s}}{\mbox{keV} }\right )</math>
+
Question: Will a thicker downstream exit window increase the positron production efficiency by providing more material for a brehm photon to pair produce in?
  
<math>\left( \frac{\mbox{keV}}{\mbox{cm}^2 \mbox{e}^-}\right) = \left( \frac{\mbox{W} }{\mbox{cm}^2 } \right )</math>
 
  
==Results Table==
+
Positrons were counted exiting a ideal 0.2 Tesla solenoid that was 15 cm long.  A ten MeV electron beam with a 0.5 cm cylindrical radius impinged a 2mm thick PbBi liquid target that had a surface area of 2.54 cm x 2.54 cm.  A 0.25 mm thick stainless steel entrance window was used. 
  
 +
Target is at -106 mm, entrance SS window is at -108.25 mm , exit SS window is at -103.75 mm, A sensitive detector for positron is placed at Z= +44mm.  The sensitive detector is a cylinder of radius 11.74 cm.
 
 
 
{| border="1"
 
{| border="1"
 
{| border="1"
 
{| border="1"
| Beam Pipe Radius (mm) || Hot Spot (<math>keV/cm^2/e^-</math>)
+
| SS Exit WIndow Thickness (mm) || Positrons/Million electrons
 
|-
 
|-
| 34.8    || 5
+
|0.|| 1142,1096,1149,1073,1083 = 1109 +/- 35
 +
|-
 +
| 0.25  || 774,836,800,785,798 = 798 +/- 23
 
|-
 
|-
47.5    ||
+
0.5    ||   693,704,713,697,715 = 704 +/- 10
 
|-
 
|-
|  60.2  ||
+
1.0   ||   587,606,548,592,550 =577 +/- 26
|-
+
|+
72.9   ||
 
|-
 
| 97.4    ||
 
|-
 
 
|}
 
|}
  
=Converter target properties=
 
 
Definition of Lead Bismuth
 
 
 
1cm diameter target
 
2 mm thick PbBi
 
 
0.5 Tesla solenoid
 
 
 
Desire to know
 
 
Emmittance (mrad * mm)
 
 
dispersion (Delta P/P)  (mradian/1000th  mm/1000th)
 
 
of electrons after the PbBi target.
 
 
 
pole face rotation in vertical plane.
 
 
=G4BeamLine and MCNPX=
 
 
 
==Target thickness optimization==
 
 
===[[PbBi_THickness_GaussBeam]]===
 
Dmitry's processing of Tony's GEANT simulations showing transverse phase space portrait (left) and longitudinal phase space portrait (right). Phase space portraits show coordinate x or y vs
 
diveregense=px/pz or py/pz (or time vs kinetic energy ). Captions show:
 
 
1. geometric (not normalized) emittance for transverse and emittance for longitudinal phase space portraits (ellipse areas divided by "pi")
 
 
2. Twiss parameters
 
 
3. Ellipse centroid for longitudinal phase portrait
 
 
4. sqrt(beta*emittance) and sqrt(gamma*emittance) - half sizes of the projections of the ellipses on the coordinate and divergence axes respectively.
 
 
Electrons - RMS
 
 
[[File:Ed1.png| 400 px]]
 
 
Electrons - 68.2% core
 
 
[[File:Ed2.png| 400 px]]
 
 
Positrons - RMS
 
 
[[File:Pd1.png| 400 px]]
 
 
Positrons - 68.2% core
 
 
[[File:Pd2.png| 400 px]]
 
 
=== [[PbBi_THickness_CylinderBeam]]===
 
Dmitry's processing of Tony's GEANT simulations showing transverse phase space portrait (left) and longitudinal phase space portrait (right). Phase space portraits show coordinate x or y vs
 
diveregense=px/pz or py/pz (or time vs kinetic energy ). Captions show:
 
 
1. geometric (not normalized) emittance for transverse and emittance for longitudinal phase space portraits (ellipse areas divided by "pi")
 
 
2. Twiss parameters
 
 
3. Ellipse centroid for longitudinal phase portrait
 
 
4. sqrt(beta*emittance) and sqrt(gamma*emittance) - half sizes of the projections of the ellipses on the coordinate and divergence axes respectively.
 
 
Electrons - RMS
 
 
[[File:E1.png| 400 px]]
 
 
Electrons - 68.2% core
 
  
[[File:E2.png| 400 px]]
+
;Conclusion 1: Positron production efficiency improves when the exit window is made thinner
  
Positrons - RMS
+
;Conclusion 2 : You loose about 28 +/- 4 % of the positrons in the 0.25 mm thick SS exit window.
  
[[File:P1.png| 400 px]]
+
=Background studies=
  
Positrons - 68.2% core
+
==Brem Spectrum==
  
[[File:P2.png| 400 px]]
+
Below is the photon energy distribution (from Brem & pair production) using a 2mm Pb target for two different incident electron energies; 6 and 10 MeV.  The photons are 1 cm downstream of the target and intersection a large forward region.
  
=== [[PbBi_THickness_PntSource]]===
+
[[File:PbBi_Brem_6-10MeV_4-7-16.png | 200 px]]
  
Electrons and Positrons after 2mm of LBE:
+
insert photon spacial distributions
  
Electrons:
+
Now move the scoring region downstream to a position representing the location of a NaI detector.
 
 
[[File:e01.png| 200 px]][[File:e02.png| 200 px]]
 
 
 
Positrons:
 
 
 
[[File:p01.png| 200 px]][[File:p02.png| 200 px]]
 
 
 
===Energy Deposition in Target system (Heat)===
 
 
 
 
 
[[File:ElectronTracks.png| 200 px]][[File:PhotonTracks.png| 200 px]]
 
 
 
[[File:ElectronEnergy.png| 200 px]][[File:PhotonEnergy.png| 200 px]]
 
 
 
MCNPX simulations of energy deposition into different cells are below. There is a slight overestimate (they add up to about 120%). Positrons contribute less than 1% of electrons' contribution. No magnetic filed is assumed.
 
 
 
[[File:Model.png| 400 px]]
 
 
 
[[File:Tablen1.png| 200 px]]
 
 
 
[[File:Tablen2.png| 200 px]]
 
 
 
==Solenoid==
 
 
 
 
 
Inner Radiusu=
 
 
 
Outer Radius =
 
 
 
Length =
 
 
 
Current=
 
 
 
Magnetic Field Map in cylindrical coordinates (Z & R) from Niowave
 
  
 
=Beam Line Design=
 
=Beam Line Design=

Latest revision as of 21:39, 8 June 2016

Development of a Positron source using a PbBi converter and a Solenoid

Conclusions

  1. A 0.3 (0.6) Tesla Solenoid with a diameter to allow a 9.74 (3.94) cm diameter pipe would collect a positron per thousand incident electrons on a 2mm thick LBE target with 0.25 mm thick SS windows.
  2. A 15 cm long, 0.2 Tesla solenoid with a 3.94 diameter beam pipe would collect a positron per two thousand electrons impinging a 2mm thick LBE target with 0.25 mm thick SS windows.
  3. A 4 Tesla Solenoid will remove beam pipe heating from scattered electrons downstream of the target when using a 3.94 cm diameter beam pipe.

Reports

Niowave_Report_11-30-2015


deadline 4/12/16


Niowave_9-2015

Niowave_10-2015

Niowave_11-2015

Niowave_12-2015

Niowave_1-2016

Niowave_2-2016

Niowave_3-2016

Niowave_4-2016

Niowave_5-2016

Niowave_6-2016

Task List

0.) 34.8 mm pipe, 0.0 -> 0.5 Tesla, E= 6,8,10 MeV.


1.) Create a positron (10,000 positrons) and electron event file containing t,x,y,z,Px,Py,Pz for positrons exiting the solenoid and an incident Gaussian beam 1cm in diameter and with a sigma of 1cm.

compare distributions with and without solenoid.

2.) Determine the back ground when using a 3.48 diameter beam pipe and Solenoid field of 0.2 for a NaI detector placed at

3.) Experiment, install dipole and solenoid in the tunnel.

Beam Pipe Heating

PbBi_BeamPipeHeatin_2015

Converter target properties

PbBi_NioWave_TargetProperties_2015


Target thickness optimization

PbBi_THickness_CylinderBeam

PbBi_THickness_GaussBeam

PbBi_THickness_PntSource

Solenoid

Uniform ideal Solenoid

PbBi_BeamPipeHeating_w_Solenoid_2015

PbBi_60cmLong_Solenoid_Collection_Efficiency_2015

Positron & Electron event files

PbBi_PosEventFiles_VaccumGaps_2015

PbBi_PosEventFiles_NoGaps_2016

Solenoid Map

Inner Radiusu=

Outer Radius =

Length =

Current=

Magnetic Field Map in cylindrical coordinates (Z & R) from Niowave

Rear Window Thickness

Question: Will a thicker downstream exit window increase the positron production efficiency by providing more material for a brehm photon to pair produce in?


Positrons were counted exiting a ideal 0.2 Tesla solenoid that was 15 cm long. A ten MeV electron beam with a 0.5 cm cylindrical radius impinged a 2mm thick PbBi liquid target that had a surface area of 2.54 cm x 2.54 cm. A 0.25 mm thick stainless steel entrance window was used.

Target is at -106 mm, entrance SS window is at -108.25 mm , exit SS window is at -103.75 mm, A sensitive detector for positron is placed at Z= +44mm. The sensitive detector is a cylinder of radius 11.74 cm.

SS Exit WIndow Thickness (mm) Positrons/Million electrons
0.0 1142,1096,1149,1073,1083 = 1109 +/- 35
0.25 774,836,800,785,798 = 798 +/- 23
0.5 693,704,713,697,715 = 704 +/- 10
1.0 587,606,548,592,550 =577 +/- 26


Conclusion 1
Positron production efficiency improves when the exit window is made thinner
Conclusion 2
You loose about 28 +/- 4 % of the positrons in the 0.25 mm thick SS exit window.

Background studies

Brem Spectrum

Below is the photon energy distribution (from Brem & pair production) using a 2mm Pb target for two different incident electron energies; 6 and 10 MeV. The photons are 1 cm downstream of the target and intersection a large forward region.

PbBi Brem 6-10MeV 4-7-16.png

insert photon spacial distributions

Now move the scoring region downstream to a position representing the location of a NaI detector.

Beam Line Design

PbBi_BeamLine_Elements

goals for JLab

Positrons#Simulations