Abstract
When a relativistic beam moves along a curved trajectory it loses energy on coherent radiation. The effect of this radiation on the beam dynamics is described by the so call coherent synchrotron radiation (CSR) longitudinal wake field. Among different models of the CSR wake, the simplest is the one-dimensional (1D) one where the beam is treated as a line-charge. The self-field of the beam on a curved trajectory also creates a transverse component of the force. Unfortunately, there is a confusion in the literature as to whether a 1D model can be worked out for the transverse force inside the beam. In this paper, we show how such a 1D model can be consistently derived for a general curvilinear beam orbit if one formulates the equations of motion for the beam particles in Hamiltonian form and uses a renormalized transverse force. Unfortunately, this scheme cannot be applied to the classical problem of relativistic beam passing through a single bending magnet, because the scalar potential in the initial conditions for the Hamiltonian variables cannot be defined in the 1D model. In this case, one should use the 3D transverse force, for which we derive analytical expressions. For the steady state, our calculations show an excellent agreement with computer simulations. We also calculate the transient effects for this force at the entrance to and the exit from the bend. Our results provide a new way to accommodate the transverse force into the existing and new simulation codes which is important for many applications of the high-current, small-emittance relativistic beams.
Highlights
Self-fields often play an important role in the dynamics of high-current beams of charged particles
Can a 1D model for the transverse force be worked out, similar to the 1D model of the longitudinal coherent synchrotron radiation (CSR) wake field? In the 1D model the beam is represented by the charge density per unit length, λðs − ctÞ, where s is the path length measured along the orbit, and we assume that the beam particles move with the speed of light
We showed that formulating the equations of motion of particles in a relativistic beam in Hamiltonian form and renormalizing the transverse force, allows one to calculate this force in 1D, or line-charge, approximation
Summary
Self-fields often play an important role in the dynamics of high-current beams of charged particles. The first studies of the steady-state CSR longitudinal wake were carried out in 1D approximation, that is for a line-charge beam with a vanishing transverse size [8,9,10]. This 1D model was later extended for the case of a bending magnet of finite length [11,12], and for a beam line with several bending magnets [13,14,15]. To convert our formulas for the force to SI units, one has to replace the charge Q (or charge per unit length or per unit volume) by Q=4πε0 where ε0 is the permittivity of free space
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
