English

X-ray Interferometry Using a Modulated Phase Grating: Theory and Experiments

Optics 2024-11-06 v1 Instrumentation and Detectors Medical Physics

Abstract

X-ray grating interferometry allows for the simultaneous acquisition of attenuation, differential-phase contrast, and dark-field images, resulting from X-ray attenuation, refraction, and small-angle scattering, respectively. The modulated phase grating (MPG) interferometer is a recently developed grating interferometry system capable of generating a directly resolvable interference pattern using a relatively large period grating envelope function that is sampled at a pitch that allows for X-ray spatial coherence using a microfocus X-ray source or by use of a source G0 grating that follows the Lau condition. We present the theory of the MPG interferometry system for a 2-dimensional staggered grating, derived using Fourier optics, and we compare the theoretical predictions with experiments we have performed with a microfocus X-ray system at Pennington Biomedical Research Center, LSU. The theoretical and experimental fringe visibility is evaluated as a function of grating-to-detector distance. Quantitative experiments are performed with porous carbon and alumina samples, and qualitative analysis of attenuation and dark-field images of a dried anchovy are shown.

Keywords

Cite

@article{arxiv.2404.14584,
  title  = {X-ray Interferometry Using a Modulated Phase Grating: Theory and Experiments},
  author = {Hunter Meyer and Joyoni Dey and Sydney Carr and Kyungmin Ham and Leslie G. Butler and Kerry M. Dooley and Ivan Hidrovo and Markus Bleuel and Tamas Varga and Joachim Schulz and Thomas Beckenbach and Konradin Kaiser},
  journal= {arXiv preprint arXiv:2404.14584},
  year   = {2024}
}

Comments

22 pages, 13 figures. This is a pre-print

R2 v1 2026-06-28T16:02:55.389Z