Cyclotrons2016 - List of Authors (Jones, F.W.)

Paper	Title	Page
THD03	Recirculating Electron Beam Photo-converter for Rare Isotope Production	383
	A. Laxdal, R.A. Baartman, I.V. Bylinskii, F.W. Jones, T. Planche, A. Sen TRIUMF, Canada's National Laboratory for Particle and Nuclear Physics, Vancouver, Canada G. Ganesh UW/Physics, Waterloo, Ontario, Canada
	Funding: TRIUMF receives federal funding via a contribution agreement through the National Research Council of Canada. ARIEL & e-linac construction are funded by BCKDF and CFI. The TRIUMF 50 MeV electron linac has the potential to drive cw beams of up to 0.5 MW to the ARIEL photo-fission facility for rare isotope science. Due to the cooling requirements, the use of a thick Bremsstrahlung target for electron to photon conversion is a difficult technical challenge in this intensity regime. Here we present a different concept in which electrons are injected into a small storage ring where they make multiple passes through a thin internal photo-conversion target, eventually depositing their remaining energy in a central core absorber which can be independently cooled. We discuss design requirements and propose a set of design parameters for the Fixed Field Alternating Gradient (FFAG) ring. Using particle simulation models, we estimate various beam properties, and electron loss control.
	Slides THD03 [6.773 MB]
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Paper

Title

Page

Recirculating Electron Beam Photo-converter for Rare Isotope Production

383

A. Laxdal, R.A. Baartman, I.V. Bylinskii, F.W. Jones, T. Planche, A. Sen
TRIUMF, Canada's National Laboratory for Particle and Nuclear Physics, Vancouver, Canada
G. Ganesh
UW/Physics, Waterloo, Ontario, Canada

Funding: TRIUMF receives federal funding via a contribution agreement through the National Research Council of Canada. ARIEL & e-linac construction are funded by BCKDF and CFI.
The TRIUMF 50 MeV electron linac has the potential to drive cw beams of up to 0.5 MW to the ARIEL photo-fission facility for rare isotope science. Due to the cooling requirements, the use of a thick Bremsstrahlung target for electron to photon conversion is a difficult technical challenge in this intensity regime. Here we present a different concept in which electrons are injected into a small storage ring where they make multiple passes through a thin internal photo-conversion target, eventually depositing their remaining energy in a central core absorber which can be independently cooled. We discuss design requirements and propose a set of design parameters for the Fixed Field Alternating Gradient (FFAG) ring. Using particle simulation models, we estimate various beam properties, and electron loss control.

Slides THD03 [6.773 MB]

Export •

reference for this paper using ※ BibTeX, ※ LaTeX, ※ Text/Word, ※ RIS, ※ EndNote (xml)