@article{oai:repo.qst.go.jp:00074658,
 author = {Aprile, Daniele and Agostinetti, P. and Baltador, C. and Denizeau, S. and 平塚, 淳一 and 市川, 雅浩 and 柏木, 美恵子 and 小島, 有志 and Marconato, N. and Pimazzoni, A. and Sartori, E. and Serianni, G. and Veltri, P. and Yoshida, M. and Chitarin, G. and Hiratsuka, Junichi and Ichikawa, Masahiro and Kashiwagi, Mieko and Kojima, Atsushi},
 issue = {070001},
 journal = {AIP Conference Proceedings},
 month = {Dec},
 note = {During 2016, a joint experimental campaign was carried out by QST and Consorzio RFX on the Negative Ion Test Stand (NITS) at the QST Naka Fusion Institute, Japan, with the purpose of validating some design solutions adopted in MITICA, which is the full-scale prototype of the ITER NBI, presently under construction at Consorzio RFX, Padova, Italy.
The main purpose of the campaign was to test a novel technique, for suppressing the beamlet criss-cross magnetic deflection. This new technique, involving a set of permanent magnets embedded in the Extraction Grid, named Asymmetric Deflection Compensation Magnets (ADCM), is potentially more performing and robust than the traditional electrostatic compensation methods.
The results of this first campaign confirmed the effectiveness of the new magnetic configuration in reducing the criss-cross magnetic deflection. Nonetheless, contrary to expectations, a complete deflection correction was not achieved. By analyzing in detail the results, we found indications that a physical process, taking place just upstream of the plasma grid, was giving an important contribution to the final deflection of the negative ion beam. This process appears to be related to the drift of negative ions inside the plasma source, in the presence of a magnetic field transverse to the extraction direction, and results in a non-uniform ion current density extracted at the meniscus.
Therefore, the numerical models adopted in the design were improved by including this previously disregarded effect, so as to obtain a much better matching with the experimental results. Based on the results of the first campaign, new permanent magnets were designed and installed on the Extraction Grid of NITS. A second QST-Consorzio RFX joint experimental campaign was then carried out in 2017, demonstrating the complete correction of the criss-cross deflection and confirming the validity of the novel magnetic configuration and of the hypothesis behind the new models.
This contribution presents the results of the second joint experimental campaign on NITS along with the overall data analysis of both campaigns, and the description of the improved models. A general picture is given of the relation among magnetic field, beam energy, meniscus non-uniformity and beamlet deflection, constituting a useful database for the design of future machines.},
 pages = {1--8},
 title = {Complete compensation of criss-cross deflection in a negative ion accelerator by magnetic technique},
 volume = {2052},
 year = {2018}
}