Abstract
The LANL/AES normal-conducting radio-frequency injector has been tested at cw cathode gradients up to $10\text{ }\text{ }\mathrm{MV}/\mathrm{m}$. Field-emission electrons from a roughened copper cathode are accelerated to beam energy as high as 2.5 MeV and impinge on a stainless steel target. The energies of the resulting bremsstrahlung photons are measured at varying levels of injector cavity rf power corresponding to different accelerating gradients. At low cavity power, the bremsstrahlung spectra exhibit well-defined end-point energies at the positions where the number of single-photon events decreases to one ($\mathrm{S}/\mathrm{N}\text{ }\mathrm{\text{ratio}}=1$). Increasing the cavity power raises the probability of two-photon events in which two photons simultaneously arrive at the detector and register counts at twice the photon energy. The end-point energies at high cavity power are recorded at positions where the single-photon events transition to two-photon events. The measured end-point energies using this method are in excellent agreement with PARMELA calculations based on the cavity gradients deduced from the cavity rf power measurements.
Highlights
Recent success of the Linac Coherent Light Source testifies to the importance of high-brightness electron beams to the performance of x-ray free-electron lasers (XFEL)
We report the first cw (100% duty factor) operation of the normalconducting radio-frequency (NCRF) injector at cathode gradients up to 10 MV=m and experimental results that validate the existence of such gradients in the LANL/Advanced Energy System (AES) injector with field emission from a roughened metal cathode
We report the first cw operation of a normal-conducting rf injector at cathode gradients up to 9:8 Æ 0:2 MV=m
Summary
Recent success of the Linac Coherent Light Source testifies to the importance of high-brightness electron beams to the performance of x-ray free-electron lasers (XFEL). High-duty operation requires new designs of NCRF injectors that can operate with semiconductor photocathodes at relatively low gradients to minimize ohmic heating on the rf surfaces, but still produce nC electron bunches with good emittance. New ideas for emittance compensation, e.g., rf focusing, higher-order magnetic modes, and external superconducting solenoid, have been proposed but far nC bunch charge in a single rf cycle has not been measured [11,12,13] Another issue with SRF guns is the potential incompatibility between the multialkali cathodes and the niobium superconducting surfaces, i.e., contamination of the superconducting surfaces by the materials coming off the photocathodes. We show the feasibility of producing a low-emittance beam with relatively low accelerating gradients by properly matching the electron beam radius to the invariant envelope
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