Abstract
A half-cell superconducting rf electron gun is designed to provide 0.5 A, 2 MeV beam for the Brookhaven National Laboratory R Energy Recovery Linac. Total rf power of 1 MW must be delivered to beam to meet the beam current and energy specifications, resulting in very strong coupling. Two opposing fundamental power couplers (FPCs) are employed to minimize the transverse kick to beam traversing the structure and to halve the power through the coupler. A single-window coaxial coupler has been designed to meet the average power and rf coupling requirements. The coupler features a planar beryllia rf window for better handling high thermal stresses and a ``pringle''-shaped tip of the antenna for enhancing rf coupling. Two FPCs have been fabricated and tested in preparation for the gun cryomodule assembly. A room-temperature test stand was used for conditioning couplers in full reflection regime with variable phase of the reflecting wave. The couplers were tested up to 250 kW in pulse mode and 125 kW in cw mode at different settings of the reflecting wave phase to expose all rf surfaces along the couplers to high fields. Several multipacting barriers were encountered and successfully processed away. The rf power levels, at which multipacting was found, match well those found in computer simulations.
Highlights
A superconducting rf (SRF) gun photoinjector [1] was chosen to generate high-current, high-brightness electron beam for the Energy Recovery Linac (ERL) at Brookhaven National Laboratory (BNL) [2]
The fundamental power couplers (FPCs) conditioning began in various pulse modes, from 100 s=10 ms to 2 ms=10 ms pulse length/period, followed by cw mode with gradual increase of rf power to the maximum value
The rf power was automatically increased or decreased depending on vacuum level at the two rf windows relative to three set points according to the following algorithm
Summary
A superconducting rf (SRF) gun photoinjector [1] was chosen to generate high-current, high-brightness electron beam for the Energy Recovery Linac (ERL) at Brookhaven National Laboratory (BNL) [2]. The 704MHz, half-cell SRF gun requires total rf power of 1 MW in order to meet the beam current and energy specifications (0.5 A, 2 MeV). The coupling scheme is similar to that of the Cornell ERL injector [3], but the coupler design is derived from the fundamental power coupler for Spallation Neutron Source (SNS) superconducting cavities [4]. To ensure that the FPCs are able to achieve the required power and avoid contamination of the SRF gun, they were cleaned in a particulate-free environment, vacuum baked, and tested at a conditioning facility prior to installation in the gun.
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