Transient fields of coherent synchrotron radiation in a rectangular pipe

TL;DR

This paper derives an exact analytical solution for the transient electromagnetic field of synchrotron radiation in a rectangular pipe, including coherent, incoherent, and space charge components, and discusses the paraxial approximation's validity.

Contribution

It provides the first exact analytical wave equation solution for synchrotron radiation fields in a curved rectangular pipe, encompassing multiple radiation components.

Findings

Exact solution includes coherent, incoherent, and space charge fields.

Numerical Fourier transform yields time-domain fields.

Discussion on the paraxial approximation's applicability.

Abstract

We found an exact analytical solution of the wave equation for a transient electromagnetic field of synchrotron radiation in the frequency domain. The exact solution represents the field which consists of the coherent and incoherent components of synchrotron radiation and the space charge field of the particle beam moving in a bending magnet. The field in the time domain is gotten by numerically Fourier transforming the values of the field calculated using the exact solution. The beam has an arbitrary charge density and current density which satisfy the equation of continuity. The beam is moving in a perfectly conducting rectangular pipe which is uniformly curved in a semi-infinite bending magnet. The exact solution is not self-consistent, i.e., this is an exact expression of the field for a given beam current. We do not solve the equation of motion of the beam in the present paper. On the basis of the exact expression of the field found in the present study, we discuss the applicability and accuracy of the paraxial approximation which is sometimes used to calculate the field and spectrum of coherent or incoherent synchrotron radiation.