Difference between revisions of "JPOS09"

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Positron_Workshop_2009 : March 25-27, 2009
 
Positron_Workshop_2009 : March 25-27, 2009
  
By September 2009:  
+
= Foreword=
 +
<pre>
 +
Below we would like to write up an introduction to the JPOS09 proceedings.  
 +
We need 1 paragraph on the nuclear physics using GeV positrons and one paragraph
 +
on thermal positron uses.  A paragraph reviewing other positron sources and
 +
their capabilities.  A paragraph identifying the more promising methods for
 +
positron production with CEBAF and an estimate of the beam properties.
 +
</pre>
  
 
= Wed 3/25/09 =
 
= Wed 3/25/09 =
Line 13: Line 20:
 
looking for positron currents of 1 <math>\mu</math> A in Hall C or 100 nA in Hall B.
 
looking for positron currents of 1 <math>\mu</math> A in Hall C or 100 nA in Hall B.
  
 +
=Positron production=
 +
==Energy options==
 +
At >  50 GeV incident electron energies, an undulator can be used to generate MeV energy photons which pair produce in a target.  You get about 200 photons for each incident electron?
 +
 +
At between 1 and 50 GeV, back scattered compton photons may be the optimal choice for producing positrons.
 +
 +
The conventional method of using a converter target my be the best choice for incident electron energies less than 1 GeV.
 +
 +
The undulator and compton techniques create polarized photons and then polarized positrons.  For the conventional method you could use off axis bremmstrahlung to create linear photons or polarize the incident electrons and have the polarization transfer.
 +
 +
== Thermal energy production==
 +
 +
Sergey Chemerisov was able to capture 100 more transmitted positrons (positrons emitted on the same side of the target as the incoming electron beam) than reflected positrons at 20 MeV incident electron energies.
 +
 +
Thermal positron rates of <math>10^{11}</math> e+/sec
 +
 +
== Converter target choice==
 +
 +
Alexander Mikhailichenko suggested using liquid Bismuth as the converter target and a high current incident electron beam ( mA).  The target would need to handle 50 MW of power.  You may get one positron for 500 incident electrons.
 +
 +
Target is 55.51% Bi and 44.49 % Pb by mass and is liquid at 159.5 C.
 +
 +
The loop needs to be Ti (melting point 1668 C).
  
 
=Polarimetry=
 
=Polarimetry=
Line 26: Line 56:
  
 
How big is the user thermal positron user community?
 
How big is the user thermal positron user community?
 +
 +
Need to organize the community, perhaps write a 5 year long range plan, then present plan to JLab management and then DOE.
 +
 +
=Proceedings=
 +
 +
==Session 3==
 +
 +
Session three focused on positron sources developed at several institutions and the transference of those experiences towards the design of a positron source at JLab for the CEBAF.  The first contribution to the session provided an overview of the three standard positron production techniques; conventional, undulator, and laser compton.  The second contributor reported on the performance of a polarized positron source tested at SLAC which observed positrons polarized up to 80%.  The next contributor described a possible CEBAF positron source design based upon the experiences of SLAC and the Cornell Positron Source.  The final two contributions to the session presented descriptions of positron sources based on lower energy, MeV, incident electron beams.  The performance of a positron source  using a 20 MeV linac at ANL was described and it was predicted that the highest efficiency for producing thermal positrons would occur for  incident electron energies between 40 an 60 MeV.  The session ended with a description of a polarized source using a 5.5 MeV linac which anticipates producing an 80 nA positron beam.
 +
 +
 +
{|border="1"  |cellpadding="20" cellspacing="0
 +
|-
 +
|Topic || speaker || talk || edited talk
 +
|-
 +
|Positron Development for Accelerators and Colliders || Wei Gai, Argonne National Lab wg@hep.anl.gov ||[[Image:WeiGai_JPOS09.doc]] ||[[Image:WeiGai_JPOS09_Edited.doc]]
 +
|-
 +
|Polarized Positrons & Polarimetry || Peter Schuler, DESY Peter.Schuler@desy.de|| [[Image:PeterSchuler_JPOS09.doc]]|| [[Image:PeterSchuler_JPOS09_Edited.doc]]
 +
|-
 +
|High Power Target and Collection Optics for Positron Production ||Alexander Mikhailichenko, Cornell University aam10@cornell.edu||[[Image:Alexander_Mikhailichenko_JPOS09.doc]]||[[Image:Alexander_Mikhailichenko_JPOS09_Edited.doc]]
 +
|-
 +
|Generation of high intensity beam of thermal positrons using 20 MeV electron linac|| Sergey Chemerisov, Argonne National Lab chemerisov@anl.gov||[[Image:Sergey_Chemerisov_JPOS09.doc]]||[[Image:Sergey_Chemerisov_JPOS09_Edited.doc]]
 +
|-
 +
|Positron production at CEA/Saclay ||Yves Sacquin, Saclay yves.sacquin@cea.fr|| [[Image:Yves_Sacquin_JPOS09.doc]]||[[Image:Yves_Sacquin_JPOS09_Edit.doc]]
 +
|}
  
 
[http://wiki.iac.isu.edu/index.php/Positrons Go Back]
 
[http://wiki.iac.isu.edu/index.php/Positrons Go Back]

Latest revision as of 16:14, 9 June 2009

http://conferences.jlab.org/JPOS09/

JPOS09 Poster.jpg

Positron_Workshop_2009 : March 25-27, 2009

Foreword

Below we would like to write up an introduction to the JPOS09 proceedings.  
We need 1 paragraph on the nuclear physics using GeV positrons and one paragraph 
on thermal positron uses.  A paragraph reviewing other positron sources and 
their capabilities.  A paragraph identifying the more promising methods for 
positron production with CEBAF and an estimate of the beam properties.

Wed 3/25/09

2 [math]\gamma[/math] exchange

looking for positron currents of 1 [math]\mu[/math] A in Hall C or 100 nA in Hall B.

Positron production

Energy options

At > 50 GeV incident electron energies, an undulator can be used to generate MeV energy photons which pair produce in a target. You get about 200 photons for each incident electron?

At between 1 and 50 GeV, back scattered compton photons may be the optimal choice for producing positrons.

The conventional method of using a converter target my be the best choice for incident electron energies less than 1 GeV.

The undulator and compton techniques create polarized photons and then polarized positrons. For the conventional method you could use off axis bremmstrahlung to create linear photons or polarize the incident electrons and have the polarization transfer.

Thermal energy production

Sergey Chemerisov was able to capture 100 more transmitted positrons (positrons emitted on the same side of the target as the incoming electron beam) than reflected positrons at 20 MeV incident electron energies.

Thermal positron rates of [math]10^{11}[/math] e+/sec

Converter target choice

Alexander Mikhailichenko suggested using liquid Bismuth as the converter target and a high current incident electron beam ( mA). The target would need to handle 50 MW of power. You may get one positron for 500 incident electrons.

Target is 55.51% Bi and 44.49 % Pb by mass and is liquid at 159.5 C.

The loop needs to be Ti (melting point 1668 C).

Polarimetry

P. Schuller (DESY) has the iron block used in E-166 at SLAC for the compton transmission polarimeter. The incident photon Energy went up to 8 MeV.

We could measure positron polarization by measuring the polarization of photons from the positron annihilation. Compton scattering depends on the polarization of the struck atomic electrons. An external B-field will polarize the FE block. You can either flip the direction of the B-file or the direction of the incident photon polarization to measure the photon polarization.

The IAC could make a compton transmission polarimeter to use on the photo-fission experiment as well as a proto-type for JLab.


Thermal positrons

How big is the user thermal positron user community?

Need to organize the community, perhaps write a 5 year long range plan, then present plan to JLab management and then DOE.

Proceedings

Session 3

Session three focused on positron sources developed at several institutions and the transference of those experiences towards the design of a positron source at JLab for the CEBAF. The first contribution to the session provided an overview of the three standard positron production techniques; conventional, undulator, and laser compton. The second contributor reported on the performance of a polarized positron source tested at SLAC which observed positrons polarized up to 80%. The next contributor described a possible CEBAF positron source design based upon the experiences of SLAC and the Cornell Positron Source. The final two contributions to the session presented descriptions of positron sources based on lower energy, MeV, incident electron beams. The performance of a positron source using a 20 MeV linac at ANL was described and it was predicted that the highest efficiency for producing thermal positrons would occur for incident electron energies between 40 an 60 MeV. The session ended with a description of a polarized source using a 5.5 MeV linac which anticipates producing an 80 nA positron beam.


Topic speaker talk edited talk
Positron Development for Accelerators and Colliders Wei Gai, Argonne National Lab wg@hep.anl.gov File:WeiGai JPOS09.doc File:WeiGai JPOS09 Edited.doc
Polarized Positrons & Polarimetry Peter Schuler, DESY Peter.Schuler@desy.de File:PeterSchuler JPOS09.doc File:PeterSchuler JPOS09 Edited.doc
High Power Target and Collection Optics for Positron Production Alexander Mikhailichenko, Cornell University aam10@cornell.edu File:Alexander Mikhailichenko JPOS09.doc File:Alexander Mikhailichenko JPOS09 Edited.doc
Generation of high intensity beam of thermal positrons using 20 MeV electron linac Sergey Chemerisov, Argonne National Lab chemerisov@anl.gov File:Sergey Chemerisov JPOS09.doc File:Sergey Chemerisov JPOS09 Edited.doc
Positron production at CEA/Saclay Yves Sacquin, Saclay yves.sacquin@cea.fr File:Yves Sacquin JPOS09.doc File:Yves Sacquin JPOS09 Edit.doc

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