Phase-Contrast Imaging, Towards G2-less Grating Interferometry With Deep Silicon

Abstract: Conventional phase-contrast imaging entails stepping an analyser grating across the detector to resolve the interference pattern caused by the x-rays after passing through a series of gratings in a so-called Talbot-Lau interferometer. However, the analyser grating in the interferometer poses a challenge, not only due to the machinery and alignment required but also due to each exposure delivering a dose to the subject. Another downside of the analyser grating is that whilst the phase-step length can be adjusted, the x-rays allowed through the grating depend on its slit-width ratio, which cannot be changed without changing the whole grating.This thesis evaluates if the analyser grating can be removed by instead using a deep silicon photon-counting detector which can determine the photon interaction position with an uncertainty of around one micrometre. It is concluded that such a high-resolution detector will not only be able to remove the need for an analyser grating and its associated challenges, but the results also imply a three-fold increase in the contrast-to-noise ratio when dose-matching the grating-based approach with the grating-less approach. Furthermore, the conventional absorption image, which is lost when using an analyser grating, will still be available using a high-resolution detector. Finally, the removal of the analyser grating shifts most of the system conditions to the source grating and the phase grating, making it possible to design a compact unit of the two gratings for integration into a CT scanner.