Abstract
X-ray phase and dark-field imaging techniques provide complementary and inaccessible information compared to conventional X-ray absorption or visible light imaging. However, such methods typically require sophisticated experimental apparatus or X-ray beams with specific properties. Recently, an X-ray speckle-based technique has shown great potential for X-ray phase and dark-field imaging using a simple experimental arrangement. However, it still suffers from either poor resolution or the time consuming process of collecting a large number of images. To overcome these limitations, in this report we demonstrate that absorption, dark-field, phase contrast, and two orthogonal differential phase contrast images can simultaneously be generated by scanning a piece of abrasive paper in only one direction. We propose a novel theoretical approach to quantitatively extract the above five images by utilising the remarkable properties of speckles. Importantly, the technique has been extended from a synchrotron light source to utilise a lab-based microfocus X-ray source and flat panel detector. Removing the need to raster the optics in two directions significantly reduces the acquisition time and absorbed dose, which can be of vital importance for many biological samples. This new imaging method could potentially provide a breakthrough for numerous practical imaging applications in biomedical research and materials science.
Highlights
Ever since Röntgen’s discovery of X-rays in the late 19th century, there has been continuous development of apparatus to create, manipulate, and detect X-rays
An X-ray speckle tracking (XST) technique has been developed for two-dimensional (2D) and three-dimensional (3D) phase contrast imaging using a simple experimental arrangement[21,22,23,24]
In addition to use with a monochromatic X-ray beam from a high brilliance synchrotron radiation source, the proposed technique is shown to be fully compatible with polychromatic X-rays generated by a microfocus lab source
Summary
Ever since Röntgen’s discovery of X-rays in the late 19th century, there has been continuous development of apparatus to create, manipulate, and detect X-rays. We have extended this approach from a synchrotron radiation source to a lab-based microfocus X-ray source by using absorption contrast speckle instead of the conventional phase contrast speckle Both the field of view and the acquisition time have been significantly improved by using a flat panel detector with a larger pixel size. The typical transverse coherence length of an X-ray beam from a synchrotron source is a few tens of micrometres When such a partially coherent beam passes through the abrasive paper with a grain size of a few micrometres, the speckle pattern caused by interference of the randomly scattered radiation can be observed with a high spatial resolution, X-ray detector.
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