Phase-preserving beam expander for biomedical X-ray imaging

Chapman

2016

J Synchrotron Radiat

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It has been established that for cylindrically bent crystals the optimal beam characteristics occur when the geometric and single-ray foci are matched. In the beam-expanding monochromator developed for the BioMedical Imaging and Therapy beamlines at the Canadian Light Source, it was unclear how critical this 'magic condition' was for preserving the transverse coherence of the beam. A study was conducted to determine whether misalignments away from the ideal conditions would severely affect the transverse coherence of the beam, thereby limiting phase-based imaging techniques. The results were that the magic condition has enough flexibility to accommodate deviations of about AE 1 or AE 5 keV.

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Measuring the criticality of the `magic condition' for a beam-expanding monochromator

Chapman

2016

J Synchrotron Radiat

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“…Making full use of the large animal imaging stage, a feature unique to this facility (Wysokinski et al, 2007), similarly requires a larger field of view. Previous results (Martinson et al, 2014(Martinson et al, , 2015 reported on the development of a phase-preserving bent Laue beamexpanding double-crystal monochromator: two silicon (Si) crystal wafers were cylindrically bent with the concave sides facing the X-ray beam and arranged with the geometrical foci of both crystals co-located and the diffraction planes parallel ISSN 1600-5775 between each crystal as in Fig. 1.…”

Section: Introductionmentioning

confidence: 99%

Characterization of a bent Laue double-crystal beam-expanding monochromator

Samadi

Shi

et al. 2017

J Synchrotron Radiat

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A bent Laue double-crystal monochromator system has been designed for vertically expanding the X-ray beam at the Canadian Light Source's BioMedical Imaging and Therapy beamlines. Expansion by a factor of 12 has been achieved without deteriorating the transverse coherence of the beam, allowing phasebased imaging techniques to be performed with high flux and a large field of view. However, preliminary studies revealed a lack of uniformity in the beam, presumed to be caused by imperfect bending of the silicon crystal wafers used in the system. Results from finite-element analysis of the system predicted that the second crystal would be most severely affected and has been shown experimentally. It has been determined that the majority of the distortion occurs in the second crystal and is likely caused by an imperfection in the surface of the bending frame. Measurements were then taken to characterize the bending of the crystal using both mechanical and diffraction techniques. In particular, two techniques commonly used to map dislocations in crystal structures have been adapted to map local curvature of the bent crystals. One of these, a variation of Berg-Berrett topography, has been used to quantify the diffraction effects caused by the distortion of the crystal wafer. This technique produces a global mapping of the deviation of the diffraction angle relative to a perfect cylinder. This information is critical for improving bending and measuring tolerances of imperfections by correlating this mapping to areas of missing intensity in the beam.

“…where υ is the Poisson ratio for the crystal type and orientation and all other variables are as defined earlier [13]. To achieve a small focus, the requirement is that the two foci, the geometric, , and polychromatic, L, match.…”

Section: Bent Laue Diffractionmentioning

confidence: 99%

An energy dispersive bent Laue monochromator for K-edge subtraction imaging

Samadi

AIP Conference Proceedings

Bassey

et al. 2016

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A tunable Laue/bent-Laue monochromator with fixed second crystal for synchrotron radiation AIP Conference Proceedings 417, 95 (1997) Abstract. K-Edge Subtraction (KES) is a powerful synchrotron imaging method that allows the quantifiable determination of a contrast element (e.g. iodine) and matrix material (usually represented as water) in both projection imaging and computed tomography. A bent Laue monochromator has been developed that has very good focal and energy dispersive properties for KES. Approximately 5% of the vertical beam profile is involved in "edge crossing" energies, thus no splitter is employed as has been done with previous implementations where approximately 33% of the beam size was blocked. The beam can be narrowed vertically allowing a smaller crossover angle than a splitter based system which minimizes artifacts. The combination of good spatial resolution, energy dispersive properties, flux and a unique approach to data analysis make this system nearly ideal for KES.Some of the relevant details of the monochromator will be discussed, especially the focal and energy dispersive properties. Example images of the beam and the object images will be presented as well.