Energy Spectra from Electromagnetic Fields Generated by Ultra-relativistic Charged Bunches in a Perfectly Conducting Cylindrical Beam Pipe

TL;DR

This paper derives an analytical solution for electromagnetic spectra generated by ultra-relativistic charged bunches in a conducting cylindrical beam pipe, revealing interference effects and spectral behaviors useful for diagnostics and design in accelerator physics.

Contribution

It provides an exact solution to Maxwell's equations for ultra-relativistic bunches in a beam pipe, linking spectral features to source properties and interference effects.

Findings

Longitudinal fields tend to zero at ultra-relativistic speeds.

Transverse spectral content relates to source properties.

Interference effects resemble CSR phenomena in cyclic machines.

Abstract

The spectrum of electromagnetic fields satisfying perfectly conducting boundary conditions in a segment of a straight beam pipe with a circular cross-section is discussed as a function of various source models. These include charged bunches that move along the axis of the pipe with constant speed for which an exact solution to the initial-boundary value problem for Maxwell's equations in the beam pipe is derived. In the ultra-relativistic limit all longitudinal components of the fields tend to zero and the spectral content of the transverse fields and average total electromagnetic energy crossing any section of the beam pipe are directly related to the properties of the ultra-relativistic source. It is shown that for axially symmetric ultra-relativistic bunches interference effects occur that show a striking resemblance to those that occur due to CSR in cyclic machines despite the fact that in this limit the source is no longer accelerating. The results offer an analytic description showing how such enhanced spectral behaviour depends on the geometry of the source and the details of the stochastic distribution of structure within the source. They offer a viable experimental means for inferring properties of the longitudinal charge distribution of bunches with micro-structure in ultra-relativistic motion in straight segments of a beam pipe from observation of the associated electromagnetic energy spectra. They are also of relevance to design criteria where the coherence effects of such fields play a significant role.