Paper |
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MOB02 |
Progress With a New Radioisotope Production Facility and Construction of Radioactive Beam Facility at iThemba LABS |
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- J.L. Conradie, J.K. Abraham, H. Anderson, L.S. Anthony, F. Azaiez, S. Baard, R.A. Bark, A.H. Barnard, P. Beukes, J.I. Broodryk, B. Cornelius, J.C. Cornell, J.G. De Villiers, H. Du Plessis, W. Duckitt, D.T. Fourie, M.E. Hogan, I.H. Kohler, C. Lussi, J. Mira, H.W. Mostert, C. Naidoo, F. Nemulodi, M. Sakieldien, V.F. Spannenberg, G.F. Steyn, N. Stodart, I.L. Strydom, R.W. Thomae, M.J. Van Niekerk, P.A. van Schalkwyk
iThemba LABS, Somerset West, South Africa
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With the termination of the neutron and proton therapy programs at iThemba LABS, the use of the Separated Sector Cyclotron (SSC) has now shifted to nuclear physics research with both stable and radioactive ion beams, as well as biomedical research. A dedicated isotope production facility with a commercial 70 MeV H-minus cyclotron has been approved and both the cyclotron and isotope production target stations will be housed in the vaults that were previously used for the therapy programs. The status of this new facility will be reported. In the future the SSC will mostly be used for nuclear physics research, as well as the production of isotopes that cannot be produced with the 70 MeV H-minus cyclotron. At present the production of the alpha-emitting radionuclide Astatine (211At) with a 28 MeV alpha beam is being investigated. Progress with the construction of a facility for production of radioactive beams will be discussed. There will also be reports on development work on the ECR ion sources and progress with implementation of an EPICS control system.
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Slides MOB02 [10.580 MB]
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DOI • |
reference for this paper
※ https://doi.org/10.18429/JACoW-Cyclotrons2019-MOB02
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About • |
paper received ※ 13 August 2019 paper accepted ※ 24 September 2019 issue date ※ 20 June 2020 |
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MOP016 |
Vertical Focussing with a Field Gradient Spiral Inflector |
58 |
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- A.H. Barnard, J.I. Broodryk, J.L. Conradie, J.G. De Villiers, J. Mira, F. Nemulodi, R.W. Thomae
iThemba LABS, Somerset West, South Africa
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Traditional spiral inflectors suffer from vertical defocussing, leading to beam loss. In this study the electrode shape of an inflector is modified to intentionally produce transverse electric field gradients, which have a significant influence on the optics. This is done by placing the traditionally parallel electrodes at an angle relative to each other in the transverse plane, creating a quadrupole field on the central path. Varying the electrode angle along the path length creates an alternating-gradient effect. The electrode entrance and exit faces are also shaped to create quadrupoles inside the fringe field. By numerical optimisation a design with good vertical focussing is obtained. Experiments show a roughly 100% increase in transmission in cases where the buncher is turned off. However, high losses at extraction are observed with the buncher turned on, due to RF-phase spread introduced by longitudinal defocussing in the inflector. This results in an improvement of only 20% during normal cyclotron operation, and shows that an inflector should ideally focus vertically and longitudinally at the same time. Ongoing work to achieve such combined focussing is described.
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Poster MOP016 [1.410 MB]
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DOI • |
reference for this paper
※ https://doi.org/10.18429/JACoW-Cyclotrons2019-MOP016
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|
About • |
paper received ※ 13 September 2019 paper accepted ※ 24 September 2019 issue date ※ 20 June 2020 |
|
Export • |
reference for this paper using
※ BibTeX,
※ LaTeX,
※ Text/Word,
※ RIS,
※ EndNote (xml)
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