Abstract

In the last two decades, x-ray phase contrast imaging (XPCI) has attracted attention as a potentially significant improvement over widespread and established x-ray imaging. The key is its capability to access a new physical quantity (the ‘phase shift’), which can be complementary to x-ray absorption. One additional advantage of XPCI is its sensitivity to micro structural details through the refraction induced dark-field (DF). While DF is extensively mentioned and used for several applications, predicting the capability of an XPCI system to retrieve DF quantitatively is not straightforward. In this article, we evaluate the impact of different design options and algorithms on DF retrieval for the edge-illumination (EI) XPCI technique. Monte Carlo simulations, supported by experimental data, are used to measure the accuracy, precision and sensitivity of DF retrieval performed with several EI systems based on conventional x-ray sources. The introduced tools are easy to implement, and general enough to assess the DF performance of systems based on alternative (i.e. non-EI) XPCI approaches.

Highlights

  • X-ray phase contrast imaging (XPCI) is an emerging technique which exploits the x-rays phase changes occurring inside an object

  • This paper focuses on EI, many of the discussed tools could be translated to Grating interferometry (GI) or other XPCI methods

  • The result of the experimental evaluation summarized in figure 2 confirms that, at least to first approximation, the DF values are independent from the parameters of the EI setup

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Summary

Introduction

X-ray phase contrast imaging (XPCI) is an emerging technique which exploits the x-rays phase changes occurring inside an object. XPCI was first demonstrated using the x-ray interferometer proposed by Bonse and Hart in 1965 [1]. Considering the complex refractive index n = 1 − δ + iβ, the phase effects are described by the real part δ while conventional attenuation is described by β. Β and δ provide different information on the sample.

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