English

Universal mask for hard X rays

Image and Video Processing 2023-08-07 v2 Accelerator Physics Optics

Abstract

The penetrating power of X rays underpins important applications such as medical radiography. However, this same attribute makes it challenging to achieve flexible on-demand patterning of X-ray beams. One possible path to this goal is ``ghost projection'', a method which may be viewed as a reversed form of classical ghost imaging. This technique employs multiple exposures, of a single illuminated non-configurable mask that is transversely displaced to a number of specified positions, to create any desired pattern. An experimental proof-of-concept is given for this idea, using hard X rays. The written pattern is arbitrary, up to a tunable constant offset, and its spatial resolution is limited by both (i) the finest features present in the illuminated mask and (ii) inaccuracies in mask positioning and mask exposure time. In principle, the method could be used to make a universal lithographic mask in the hard-X-ray regime. Ghost projection might also be used as a dynamically-configurable beam-shaping element, namely the hard-X-ray equivalent of a spatial light modulator. The underpinning principle can be applied to gamma rays, neutrons, electrons, muons, and atomic beams. Our flexible approach to beam shaping gives a potentially useful means to manipulate such fields.

Keywords

Cite

@article{arxiv.2303.12809,
  title  = {Universal mask for hard X rays},
  author = {David Ceddia and Alaleh Aminzadeh and Philip K. Cook and Daniele Pelliccia and Andrew M. Kingston and David M. Paganin},
  journal= {arXiv preprint arXiv:2303.12809},
  year   = {2023}
}

Comments

Revised for resubmission to Optica; numerous clarifications throughout the paper; Sec. 4 (numbered item 2) and Supplement 1 Sec. 2 significantly extended; all figures and ancillary movies unchanged

R2 v1 2026-06-28T09:28:39.874Z