Equilibrium and Stability of a High-Intensity Periodically Twisted Ellipse-Shaped Charged-Particle Beam

Summary form only given. It is shown that there exists an exact paraxial cold-fluid equilibrium of a high-intensity, space-charge-dominated charged-particle beam with a periodically twisted elliptic cross section in a non-axisymmetric periodic magnetic field. Generalized envelope equations, which determine the beam envelopes, ellipse orientation, density, and internal flow velocity profiles, are derived. Effects of nonlinearities in the magnetic fields and instabilities at high vacuum phase advances are investigated. The parameter space for stable operation is identified. The beam equilibrium and stability properties are verified by two-dimensional self-consistent particle-in-cell (PIC) simulations using the MIT 2D periodic focused beam (PFB2D) code. The beam equilibrium is further verified by 3D simulations using the commercial code OmniTrak. As applications, a nonrelativistic elliptic electron beam is designed for the MIT ribbon-beam amplifier and a relativistic electron beam is designed for a high-power L-band klystron