Abstract
The Xian gamma-ray light source (XGLS) is a proposed novel high brightness gamma-ray source based on inverse Compton scattering (ICS) between the high brightness electron and laser beams. The photoinjector of the accelerator is one of the main components that determines the electron beam quality and related gamma-ray parameters [Phys. Rev. Accel. Beams 21, 030701 (2018); 20, 080701 (2017); 8, 100702 (2005)]. In order to reduce the risk of this project, a photoinjector including a laser-driven photocathode rf gun, two S-band tubes, and a diagnostic section was constructed and installed from 2016, serving as a pilot plant for the development of the key technologies for the projects. The injector is designed to deliver high quality electron bunches of typically 500 pC charge and $\ensuremath{\sim}120\text{ }\text{ }\mathrm{MeV}$ energy with low emittance and jitter at 10 Hz repetition. Initial system commissioning with an electron beam was finished in the end of 2017, with a goal of a stable 0.6--0.7 mm mrad emittance in a 500-pC bunch clearly demonstrated. In this paper, we report the experimental results and experience obtained in the commissioning, including rf gun, drive laser system, timing and synchronization system, and beam diagnostics.
Highlights
High intensity x-ray light sources based on free electron laser (FEL) and synchrotron accelerators have already set off a wave of exploring the structure and dynamics of atomic and molecular systems around the world [1,2,3,4,5,6,7,8,9]
We report the first beam results and experience obtained in the commissioning, including photocathode rf gun, drive laser system, timing and synchronization, and beam diagnostics
The phase jitter of the level rf system (LLRF) system is near 50 fs RMS that meets the synchronization needs
Summary
High intensity x-ray light sources based on free electron laser (FEL) and synchrotron accelerators have already set off a wave of exploring the structure and dynamics of atomic and molecular systems around the world [1,2,3,4,5,6,7,8,9]. Gammaray sources based on inverse Compton scattering (ICS) are currently the most feasible solution [10] Since in such sources the incident photons are boosted to high energy proportional to the square of electron beam energy, it is easy to generate high energy gamma-ray beam with much lower beam energy than FEL and synchrotron light source. Stable 500-pC bunches would be accelerated to about 360 MeV and have the emittance of less than 0.9 mm mrad This requirement would be met by careful and systemic design and construction of the photoinjector based accelerator [14,15]. Bunch charge (nC) Final beam energy (MeV) Energy jitter Bunch length (FWHM, ps) Energy spread (rms, %) Projected norm emittance (mm mrad) Repetition rate (Hz)
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