Modeling of beam acceleration for the negative ion source NIO1

Abstract

The RF negative ion source NIO1 (Negative Ion Optimization 1) [1], built at Consorzio RFX in Padova (Italy), aims at investigating basic issues of ion source physics while providing a tool to benchmark and validate beam simulation codes. On the other hand, because of its small size and its modular design, NIO1 represents a valuable testbed for DEMO relevant solutions, such as energy recovery and alternative systems for ion beam neutralization [1]. To such purposes it is important to improve NIO1 performance to make it comparable to those achieved or expected by other ITER relevant negative ion sources, such as ELISE [2] or SPIDER [3] and already a. In particular the latest NIO1 upgrades focused on reducing the co-extracted electrons by enlarging the magnetic field strength close to the plasma grid and on improving the beam optics. As anticipated in [4], a new extraction grid was designed [5] to guarantee a better optics and a significant reduction of the beamlet deflection. The present paper presents the computation of the NIO1 beam optics as a function of the operating parameters. Throughout this work, the finite element code OPERA3D [6] and the Monte Carlo particle tracing code EAMCC3D [7] were used to model the NIO1 accelerator in both its previous and new configurations. Results from simulations are also compared with the data from NIO1 diagnostic calorimeter [8].