Simulation of a concept for a compact ultrafast X-ray pulse source based on RF and THz technologies

We study through simulations a layout mixing RF and THz technologies for a compact ultrafast X-ray pulse source based on Inverse Compton Scattering (ICS), aiming to deliver few femtoseconds to sub-femtosecond pulses. The layout consists of an S-band gun as the electron source and a dielectric-loaded circular waveguide driven by a multicycle THz pulse to accelerate and longitudinally compress the bunch, before X-ray generation via ICS with a laser pulse. We detail several schemes allowing the optimization of the electron bunch properties. This optimization leads to a preliminary layout and various working points able to deliver 0.1-5 pC bunches, ranging from 15 to 18 MeV average kinetic energy, 0.4 to 5 fs rms length, 0.1% to 2.6% rms energy spread, and 5 to 13 mu m rms transverse size. Simultaneously, the beamline is kept compact (approximate to 1.3m up to the ICS point), which has not yet been achieved using only conventional RF technologies. The properties of the X-ray pulse are investigated with simulations, showing the possibility to tune its energy between 2.9 and 11.5 keV. For 400 mJ of laser energy, 1.5 x 10(4)-7.7 x 10(4) photons/pulse in 1.5% rms bandwidth or 6.2 x 10(3)-3.5 x 10(4) photons/pulse with lower bandwidths (0.56%-1.5% rms along the energy range) can be expected. The properties of the DLW and of the THz pulse driving it, the state-of-the-art of the THz pulse generation schemes, and the influence of various jitters and the limits that they should not exceed for a reasonably stable operation are finally given. Published under license by AIP Publishing.