Characterization of Hysteretic Behavior of a FeCo Magnet for the Design of a Novel Ion Gantry

In the framework of the euroSIG project and within an international collaboration between CNAO, CERN, INFN, and MedAustron, the design of a novel gantry for hadron therapy based on superconducting magnets and a downstream scanning system has been undertaken. The choice of placing the scanning system downstream of the last superconducting dipole plays a crucial role in the overall layout of the gantry, having a direct impact on its radius, weight, and cost. The proposed design for the scanning system considers two separate normal-conducting scanning magnets with a central field in the order of 1 T, three times higher than the current state-of-the-art scanning magnets for hadron therapy. Such a magnetic field value for a fast-pulsed magnet poses interesting questions regarding non-linearities due to the yoke saturation, hysteretic effects, and eddy currents. In this context, it is important to develop reliable models to study the behavior of the magnet at various levels of current and magnetic field. For this reason, we implemented two and three-dimensional simulations of a short dipole with FeCo yoke and we validated them against experimental measurements. In this paper, we focus on the modelization of the hysteretic behavior of this magnet, providing insight into the feasibility of proposed scanning magnets.