Abstract
Uncontrolled beam losses due to space-charge-induced halo generation are a concern in high intensity rings, which are characterized by high beam intensities and low uncontrolled beam loss requirements. It is therefore important to investigate the dynamics of space charge in high intensity rings. We report here the results of extensive calculations using a particle-tracking approach with a self-consistent particle-in-cell model and alternatively with a particle core model. We find that the inclusion of space charge forces provides agreement between calculated and experimentally observed beam profile shapes in the high intensity proton storage ring. We also confirm computationally the extension to rings of the accepted dynamics of halo generation with rms beam mismatch exciting the parametric resonance. In addition, we propose a new two-stage mechanism for halo production in rings in which space-charge-driven lattice resonances generate beam mismatch that excites the parametric resonance. Because of its dependence on lattice resonances, this mechanism is peculiar to rings and is capable of generating halo even from initially matched beams. It is also very sensitive to the operating point in tune space, as we show in the results of a vertical tune scan simulating injection into the Spallation Neutron Source accumulator ring. Our results extend and enhance the understanding of fundamental space charge physics, which has been developed for linear accelerators, to rings.
Highlights
Beam dynamics in high intensity rings has become very relevant due to a number of new machines under consideration, including the Spallation Neutron Source (SNS), European Spallation Source (ESS), Japan Hadron Facility (JHF), m-Collider Driver, and others
Because of the necessity of high beam intensity and low uncontrolled beam loss, space charge contributions to beam loss through halo formation are an essential concern for the SNS project
We report here the results of extensive calculations using a particle-tracking approach with a self-consistent particle-in-cell (PIC) model and alternatively with a particle core model (PCM)
Summary
Beam dynamics in high intensity rings has become very relevant due to a number of new machines under consideration, including the Spallation Neutron Source (SNS), European Spallation Source (ESS), Japan Hadron Facility (JHF), m-Collider Driver, and others These machines are characterized by large beam currents and by very stringent uncontrolled beam loss requirements.
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