Sensitive Phase Gratings for X-ray Phase Contrast - a Simulation-based Comparison

TL;DR

This paper introduces novel phase grating geometries for X-ray phase contrast imaging that double sensitivity without sacrificing visibility, demonstrated through simulation comparisons of interference patterns.

Contribution

It proposes two new grating geometries, including a novel three-level design, enabling higher sensitivity in X-ray phase contrast imaging while maintaining or improving visibility.

Findings

Proposed geometries double the sensitivity compared to conventional gratings.

Simulations show potential for improved or maintained visibility at higher sensitivities.

New designs are effective across different photon energies and coherence conditions.

Abstract

Medical differential phase contrast x-ray imaging (DPCI) promises improved soft-tissue contrast at lower x-ray dose. The dose strongly depends on both the angular sensitivity and on the visibility of a grating-based Talbot-Lau interferometer. Using a conventional x-ray tube, a high sensitivity and a high visibility are somewhat contradicting goals: To increase sensitivity, the grating period has to be reduced and/or the grating distance increased. Technically, this means using a higher Talbot order (3rd or 5th one instead of first one). This however reduces the visibility somewhat, because only a smaller part of the tube spectrum will get used. This work proposes to relax this problem by changing the phase grating geometry. This allows to double sensitivity (i.e., double the Talbot order) without reducing the visibility. One proposed grating geometry is an older binary one (75% of a period $\pi$-shifting), but applied in a novel way. The second proposed geometry is a novel one, requiring three height levels for polychromatic correction. The advantage is quantified by a simulation of the resulting interference patterns. Visibilities for the common $\pi$-shifting gratings are compared with the proposed alternative geometries. This is done depending on photon energy and opening ratio of the coherence grating G0. It shows that despite of doubled sensitivity of the proposed gratings, the overall visibility might even improve a little.