Abstract
We propose a novel alignment technique utilizing the x-ray beam of an undulator in conjunction with pinholes and position-sensitive detectors for positioning components of the accelerator, undulator, and beam line in an x-ray free-electron laser. Two retractable pinholes at each end of the undulator define a stable and reproducible x-ray beam axis (XBA). Targets are precisely positioned on the XBA using a pinhole camera technique. Position-sensitive detectors responding to both x-ray and electron beams enable direct transfer of the position setting from the XBA to the electron beam. This system has the potential to deliver superior alignment accuracy ($1\char21{}3\text{ }\ensuremath{\mu}\mathrm{m}$) for target pinholes in the transverse directions over a long distance (200 m or longer). It can be used to define the beam axis of the electron-beam\char21{}based alignment, enabling high reproducibility of the latter. This x-ray\char21{}based concept should complement the electron-beam\char21{}based alignment and the existing survey methods to raise the alignment accuracy of long accelerators to an unprecedented level. Further improvement of the transverse accuracy using x-ray zone plates will be discussed. We also propose a concurrent measurement scheme during accelerator operation to allow real-time feedback for transverse position correction.
Highlights
Several large-scale linear accelerator projects are under construction or have been proposed
Most of our discussion will be based on the geometry and parameters of the Linear CoherentLight Source (LCLS), but it can be extended to other large-scale accelerator projects. We envision that this technology could be beneficial for the International Linear Collider (ILC) project with its component alignment tolerances even more challenging than what is currently required for the x-ray free-electron laser (XFEL) projects
Since we have determined the electron-beam position when it coincides with the x-ray beam axis (XBA) at the beam position monitors (BPMs), we can hold that position of the electron beam and move the nearby quadrupole magnet to search for its center
Summary
Several large-scale linear accelerator projects are under construction or have been proposed. It includes an elaborate feedback system to maintain the pointing direction of an expanded light beam and eliminates the need for inserting and removing reference targets as required in the SLAC design, as many spheres can occupy the cross section of the light beam This system was designed to provide transverse positioning on the order of 25 m over a 300-m-long FEL. Shintake et al made a step towards overcoming these difficulties by proposing an on-axis alignment procedure using a laser beam and an Airy diffraction pattern for the SCSS x-ray FEL project [14]. They plan to enlarge the optical aperture by opening the gap of invacuum undulators during the alignment. We envision that this technology could be beneficial for the ILC project with its component alignment tolerances even more challenging than what is currently required for the XFEL projects
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