Transverse emittance dilution due to coupler kicks in linear accelerators

TL;DR

This paper investigates how coupler-induced electromagnetic fields cause emittance dilution and orbit distortions in linear accelerators, analyzing various mitigation techniques including cavity symmetry, coupler placement, and phase optimization.

Contribution

It provides a detailed analysis of coupler kick effects and evaluates multiple strategies for reducing emittance growth and orbit distortions in linacs.

Findings

Alternating coupler placement cancels orbit distortion or emittance growth, but not both simultaneously.

Phase optimization of coupler kicks reduces emittance growth independently of geometry.

Symmetrizing cavity geometry with a stub decreases off-axis fields and mitigates coupler kicks.

Abstract

One of the main concerns in the design of low emittance linear accelerators (linacs) is the preservation of beam emittance. Here we discuss one possible source of emittance dilution, the coupler kick, due to transverse electromagnetic fields in the accelerating cavities of the linac caused by the power coupler geometry. In addition to emittance growth, the coupler kick also produces orbit distortions. It is common wisdom that emittance growth from coupler kicks can be strongly reduced by using two couplers per cavity mounted opposite each other or by having the couplers of successive cavities alternation from above to below the beam pipe so as to cancel each individual kick. We therefore analyze consequences of alternate coupler placements. We show here that for sufficiently large Q values, alternating the coupler location from before to after the cavity leads to a cancellation of the orbit distortion but not of the emittance growth, whereas alternating the coupler location from before and above to behind and below the cavity cancels the emittance growth but not the orbit distortion. These compensations hold even when each cavity is individually detuned, e.g. by microphonics. Another effective method for reducing coupler kicks that is studied is the optimization of the phase of the coupler kick. This technique is independent of the coupler geometry but relies on operating on crest. A final technique studied is symmetrization of the cavity geometry in the coupler region with the addition of a stub opposite the coupler, which reduces the amplitude of the off axis fields and is thus effective for off crest acceleration as well. We show applications of these techniques to the energy recovery linac (ERL) planned at Cornell University.