Abstract
At ISAC-TRIUMF, a 500 MeV proton beam is impinged upon “thick” targets to induce nuclear reactions to produce reaction products that are delivered as a Radioactive Ion Beam (RIB) to experiments. Uranium carbide is among the most commonly used target materials which produces a vast radionuclide inventory coming from both spallation and fission-events. This can also represent a major limitation for the successful delivery of certain RIBs to experiments since, for a given mass, many isobaric isotopes are to be filtered by the dipole mass separator. These contaminants can exceed the yield of the isotope of interest by orders of magnitude, often causing a significant reduction in the sensitivity of experiments or even making them impossible.The design of a 50 kW proton-to-neutron (p2n) converter-target is ongoing to enhance the production of neutron-rich nuclei while significantly reducing the rate of neutron-deficient contaminants. The converter is made out of a bulk tungsten block which converts proton beams into neutrons through spallation. The neutrons, in turn, induce pure fission in an upstream UCx target. The present target design and the service infra-structure needed for its operation will be discussed in this paper.
Highlights
The ISAC-TRIUMF Facility [1] applies the ISOL Method [2] to produce radioisotopes for a wide range of experiments
The proton-to-neutron geometry is shown in Fig. 2 where the concept is explained: the incoming 500 MeV proton beam from the main cyclotron is directed through the centre of a hollow actinide target onto a solid tungsten cylinder in contact with two water-cooled copper brackets
The fission target is placed upstream of the converter in order to further reduce neutron-deficient nuclear reaction products via protons that are scattered by the converter
Summary
The ISAC-TRIUMF Facility [1] applies the ISOL Method [2] to produce radioisotopes for a wide range of experiments. The ISAC-TRIUMF proton-to-neutron (p2n) target, under development by a joint collaboration between TRIUMF, CERN and SCK-CEN, aims at delivering neutronrich RIBs with intensities comparable to ISAC-TRIUMF standard UCx targets, while reducing the isobaric neutrondeficient contaminants by two orders of magnitude. The proton-to-neutron geometry is shown in Fig. 2 where the concept is explained: the incoming 500 MeV proton beam from the main cyclotron is directed through the centre of a hollow actinide target onto a solid tungsten cylinder in contact with two water-cooled copper brackets.
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