Abstract
Here we will derive the general theory of the beam-breakup instability in recirculating linear accelerators, in which the bunches do not have to be at the same RF phase during each recirculation turn. This is important for the description of energy recovery linacs (ERLs) where bunches are recirculated at a decelerating phase of the RF wave and for other recirculator arrangements where different RF phases are of an advantage. Furthermore it can be used for the analysis of phase errors of recirculated bunches. It is shown how the threshold current for a given linac can be computed and a remarkable agreement with tracking data is demonstrated. The general formulas are then analyzed for several analytically solvable cases, which show: (a) Why different higher order modes (HOM) in one cavity do not couple so that the most dangerous modes can be considered individually. (b) How different HOM frequencies have to be in order to consider them separately. (c) That no optics can cause the HOMs of two cavities to cancel. (d) How an optics can avoid the addition of the instabilities of two cavities. (e) How a HOM in a multiple-turn recirculator interferes with itself. Furthermore, a simple method to compute the orbit deviations produced by cavity misalignments has also been introduced. It is shown that the BBU instability always occurs before the orbit excursion becomes very large.
Highlights
Synchrotron light sources based on energy recovery linacs (ERLs) show promise to deliver x-ray beams with both brilliance and x-ray pulse duration far superior to the values that can be achieved with storage ring technology
This is due to the fact that the emittances in an ERL are largely determined by a laser-driven source, technology which has been improving steadily over the years, and will undoubtedly improve further
To generate high brilliance high flux x rays it is necessary to accelerate beams to the energies and with the currents that are typical in these storage rings
Summary
Synchrotron light sources based on energy recovery linacs (ERLs) show promise to deliver x-ray beams with both brilliance and x-ray pulse duration far superior to the values that can be achieved with storage ring technology. To generate high brilliance high flux x rays it is necessary to accelerate beams to the energies (several GeV) and with the currents (several 100 mA) that are typical in these storage rings This would require that the linac delivers a power of order 1 GW to the beam. A theory of BBU instability in recirculating linacs, where the energy is not recovered in the linac but where energy is added to the beam when it returns after each recirculation turn, was presented in [13]. We allow many HOMs and many recirculations, and we analyze several analytically solvable cases
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