The RF-driven negative hydrogen ion source (H - , D - ) for the international fusion experiment ITER has a width of 0.9 m and a height of 1.9 m and is based on a 1/2 scale prototype source being in operation at the IPP test facilities BATMAN and MANITU for many years. Among the challenges to meet the required parameters in a caesiated source at a source pressure of 0.3 Pa or less is the challenge in size scaling of a factor of eight. As an intermediate step a 1/2 scale ITER source went into operation at the IPP test facility ELISE with the first plasma in February 2013. The experience and results gained so far at ELISE allowed a size scaling study from the prototype source towards the ITER relevant size at ELISE, in which operational issues, physical aspects and the source performance is addressed, highlighting differences as well as similarities. The most ITER relevant results are: low pressure operation down to 0.2 Pa is possible without problems; the magnetic filter field created by a current in the plasma grid is sufficient to reduce the electron temperature below the target value of 1 eV and to reduce together with the bias applied between the differently shaped bias plate and the plasma grid the amount of co-extracted electrons. An asymmetry of the co-extracted electron currents in the two grid segments is measured, varying strongly with filter field and bias. Contrary to the prototype source, a dedicated plasma drift in vertical direction is not observed. As in the prototype source, the performance in deuterium is limited by the amount of co-extracted electrons in short as well as in long pulse operation. Caesium conditioning is much harder in deuterium than in hydrogen for which fast and reproducible conditioning is achieved. First estimates reveal a caesium consumption comparable to the one in the prototype source despite the large size.
CITATION STYLE
Fantz, U., Franzen, P., Kraus, W., Schiesko, L., Wimmer, C., & Wünderlich, D. (2015). Size scaling of negative hydrogen ion sources for fusion. In AIP Conference Proceedings (Vol. 1655). American Institute of Physics Inc. https://doi.org/10.1063/1.4916443
Mendeley helps you to discover research relevant for your work.