High energy x-ray Talbot-Lau interferometer employing a microarray anode-structured target source to extend the field of view.

Abstract

High energy and large field of view (FOV) phase contrast imaging is crucial for biological and even medical applications. Although some works have devoted to achiving a large field of view at high energy through bending gratings and so on, which would be extremely challenging in medical high energy imaging. We analyze the angular shadowing effect of planar gratings in high-energy X-ray Talbot-Lau interferometer (XTLI). Then we design and develop an inverse XTLI coupled with a microarray anode-structured target source, to extend the FOV at high energy. Our experimental results demonstrate the benefit of the source in inverse XTLI and a large FOV of 106.6 mm in the horizontal direction is achieved at 40 keV. Based on this system, experiments of a mouse demonstrate the potential advantage of phase contrast mode in imaging lung tissue. We extend the FOV in a compact XTLI using a microarray anode-structured target source coupled with an inverse geometry, which eliminates grating G0 and relaxes the fabrication difficulty of G2. We believe the established design idea and imaging system would facilitate the wide applications of XTLI in high energy phase contrast imaging.