A positron source using an axially oriented crystal associated to a granular amorphous converter

XU Cheng-Hai; Robert Chehab; Peter Sievers; Xavier Artru; Michel Chevallier; Olivier Dadoun; PEI Guo-Xi; Vladimir M; Alessandro Variola

doi:10.1088/1674-1137/36/9/014

Chinese Physics C> 2012, Vol. 36> Issue(9) : 871-878 DOI: 10.1088/1674-1137/36/9/014

A positron source using an axially oriented crystal associated to a granular amorphous converter

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A non-conventional positron source using the intense γ radiation from an axially oriented monocrystal which materializes into e⁺e^- pairs in a granular amorphous converter is described. The enhancement of photon radiation by multi-GeV electrons crossing a tungsten crystal along its <111> axis is reported. The resulting enhancement of pair production in an amorphous converter placed 2 meters downstream, is also reported. Sweeping off the charged particles from the crystal by a bending magnet upstream of the converter allows a significant reduction of the deposited energy density. Substituting a granular target made of small spheres for the usual compact one, makes the energy dissipation easier. The deposited energy and corresponding heating are analyzed and solutions for cooling are proposed. The configurations studied here for this kind of positron source allow its consideration for unpolarized positrons for the ILC.

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XU Cheng-Hai, Robert Chehab, Peter Sievers, Xavier Artru, Michel Chevallier, Olivier Dadoun, PEI Guo-Xi, Vladimir M and Alessandro Variola. A positron source using an axially oriented crystal associated to a granular amorphous converter[J]. Chinese Physics C, 2012, 36(9): 871-878. doi: 10.1088/1674-1137/36/9/014

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Received: 2011-12-06
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沈阳化工大学材料科学与工程学院沈阳 110142

A positron source using an axially oriented crystal associated to a granular amorphous converter

Received Date: 2011-12-06

Accepted Date: 2012-01-16

Available Online: 2012-09-05

Abstract: A non-conventional positron source using the intense γ radiation from an axially oriented monocrystal which materializes into e⁺e^- pairs in a granular amorphous converter is described. The enhancement of photon radiation by multi-GeV electrons crossing a tungsten crystal along its <111> axis is reported. The resulting enhancement of pair production in an amorphous converter placed 2 meters downstream, is also reported. Sweeping off the charged particles from the crystal by a bending magnet upstream of the converter allows a significant reduction of the deposited energy density. Substituting a granular target made of small spheres for the usual compact one, makes the energy dissipation easier. The deposited energy and corresponding heating are analyzed and solutions for cooling are proposed. The configurations studied here for this kind of positron source allow its consideration for unpolarized positrons for the ILC.

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A positron source using an axially oriented crystal associated to a granular amorphous converter

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