Development of a high-temperature oven for the 28 GHz electron cyclotron resonance ion source

We have been developing the 28 GHz ECR ion source in order to accelerate high-intensity uranium beams at the RIKEN RI-beam Factory. Although we have generated U(35+) beams by the sputtering method thus far, we began developing a high-temperature oven with the aim of increasing and stabilizing the be...

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Veröffentlicht in:	Review of scientific instruments 2014-02, Vol.85 (2), p.02A941-02A941
Hauptverfasser:	Ohnishi, J, Higurashi, Y, Kidera, M, Ozeki, K, Nakagawa, T
Format:	Artikel
Sprache:	eng
Schlagworte:	BEAM CURRENTS CRUCIBLES ECR ION SOURCES ELECTRON CYCLOTRON-RESONANCE MACHINING MAGNETIC FIELDS OVENS PARTICLE ACCELERATORS PLASMA RADIOACTIVE ION BEAMS TUNGSTEN URANIUM URANIUM DIOXIDE
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container_end_page	02A941
container_issue	2
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container_title	Review of scientific instruments
container_volume	85
creator	Ohnishi, J Higurashi, Y Kidera, M Ozeki, K Nakagawa, T
description	We have been developing the 28 GHz ECR ion source in order to accelerate high-intensity uranium beams at the RIKEN RI-beam Factory. Although we have generated U(35+) beams by the sputtering method thus far, we began developing a high-temperature oven with the aim of increasing and stabilizing the beams. Because the oven method uses UO2, a crucible must be heated to a temperature higher than 2000 °C to supply an appropriate amount of UO2 vapor to the ECR plasma. Our high-temperature oven uses a tungsten crucible joule-heated with DC current of approximately 450 A. Its inside dimensions are ϕ11 mm × 13.5 mm. Since the crucible is placed in a magnetic field of approximately 3 T, it is subject to a magnetic force of approximately 40 N. Therefore, we used ANSYS to carefully design the crucible, which was manufactured by machining a tungsten rod. We could raise the oven up to 1900 °C in the first off-line test. Subsequently, UO2 was loaded into the crucible, and the oven was installed in the 28 GHz ECR ion source and was tested. As a result, a U(35+) beam current of 150 μA was extracted successfully at a RF power of approximately 3 kW.
doi_str_mv	10.1063/1.4849655
format	Article
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Although we have generated U(35+) beams by the sputtering method thus far, we began developing a high-temperature oven with the aim of increasing and stabilizing the beams. Because the oven method uses UO2, a crucible must be heated to a temperature higher than 2000 °C to supply an appropriate amount of UO2 vapor to the ECR plasma. Our high-temperature oven uses a tungsten crucible joule-heated with DC current of approximately 450 A. Its inside dimensions are ϕ11 mm × 13.5 mm. Since the crucible is placed in a magnetic field of approximately 3 T, it is subject to a magnetic force of approximately 40 N. Therefore, we used ANSYS to carefully design the crucible, which was manufactured by machining a tungsten rod. We could raise the oven up to 1900 °C in the first off-line test. Subsequently, UO2 was loaded into the crucible, and the oven was installed in the 28 GHz ECR ion source and was tested. As a result, a U(35+) beam current of 150 μA was extracted successfully at a RF power of approximately 3 kW.</abstract><cop>United States</cop><pmid>24593520</pmid><doi>10.1063/1.4849655</doi></addata></record>
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subjects	BEAM CURRENTS CRUCIBLES ECR ION SOURCES ELECTRON CYCLOTRON-RESONANCE MACHINING MAGNETIC FIELDS OVENS PARTICLE ACCELERATORS PLASMA RADIOACTIVE ION BEAMS TUNGSTEN URANIUM URANIUM DIOXIDE
title	Development of a high-temperature oven for the 28 GHz electron cyclotron resonance ion source
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