Abstract
Permanent magnet insertion devices (IDs), which are the main radiation generating devices in synchrotron light sources and free-electron lasers, use a time-invariant but space-periodic magnetic field to wiggle relativistic electrons for short-wavelength radiation generation. Recently, a high power microwave based undulator has also been successfully demonstrated at SLAC which promises the advantage of dynamic tunability of radiation spectrum and polarization. Such IDs employ transverse elecromagnetic fields which are periodic in both space and time to undulate the electrons. In this paper we develop a detailed theory of the principle of electromagnetic IDs from first principles for both linear and circular polarization modes. The electromagnetic equivalent definitions of undulator period (${\ensuremath{\lambda}}_{u}$) and undulator deflection parameter ($K$) are derived. In the inertial frame where the average momentum of the electron is zero, we obtain the figure-8-like trajectory for the linear polarization mode and the circular trajectory for the circular polarization mode. The corresponding radiation spectra and the intensity of harmonics is also calculated.
Highlights
The conventional insertion devices (IDs) consist of a series of alternating magnetic poles that induce a periodic local deflection in a relativistic electron beam of a synchrotron to generate intense radiation in a specific range of the spectrum
The technology of permanent magnet undulators (PMUs) has become an established art and is being pushed to its limits to satisfy the requirements of the fourth generation light sources
We have shown that in the electron frame, where the average momentum of the electron is zero, it traces a figure-8-like trajectory for the linear polarization mode and a circular trajectory for the circular polarization mode
Summary
The conventional insertion devices (IDs) (wigglers or undulators) consist of a series of alternating magnetic poles that induce a periodic local deflection in a relativistic electron beam of a synchrotron to generate intense radiation in a specific range of the spectrum. Fast dynamic control of the radiation can offer exciting scientific opportunities These limitations could be overcome by the use of high-power guided microwaves to produce a periodical transverse wiggling field. We have investigated the spectrum of the synchrotron radiation and the far-field intensity of harmonics versus the observation angle For both linear and circular polarization balanced hybrid HE1n modes, the electron trajectory in a microwave undulator and the corresponding radiation characteristics turn out to be similar to those of PMUs
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