Your search keyword '"Martinson, Mercedes"' showing total 9 results

1. Wide field imaging energy dispersive X-ray absorption spectroscopy

Author

Qi, Peng, Samadi, Nazanin, Martinson, Mercedes, Ponomarenko, Olena, Bassey, Bassey, Gomez, Ariel, George, Graham N., Pickering, Ingrid J., and Chapman, L. Dean

Published

2019

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

Author

Martinson, Mercedes, Samadi, Nazanin, Shi, Xianbo, Liu, Zunping, Assoufid, Lahsen, and Chapman, Dean

Subjects

*LIGHT sources, *MONOCHROMATORS, *MEDICAL imaging systems, *SILICON wafers, *TOPOGRAPHY, *FINITE element method

Abstract

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 phase-based 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. [ABSTRACT FROM AUTHOR]

Published

2017

3. Small and Ultra-Small Angle X-Ray Scattering Contrast Obtained With a Synchrotron-Based Shack–Hartmann Imaging System.

Author

Wiebe, Sheldon, Samadi, Nazanin, Belev, George, Martinson, Mercedes, Bassey, and Chapman, Dean

Subjects

X-ray imaging, X-ray scattering, SYNCHROTRON radiation, REFRACTION (Optics), PHOTODETECTORS, IMAGE analysis

Abstract

A number of phase based X-ray imaging methods have been developed that derive contrast from phase effects from the object which make them particularly interesting because of the ability to visualize soft tissues. Shack–Hartmann is a wave-front diagnostic technique that emerged from optics which uses ray-line beams (beamlets) to interrogate the differences in the wave-front across a beam can also be used for X-ray imaging applications with phase sensitivity. This method, which has been applied in the X-ray regime, is very simple in that it only requires a screen to prepare an array of beamlets that then pass through the object and are allowed to propagate a distance onto a pixelated detector. Absorption and refraction information can be extracted from the detected beamlets. An untapped property is the additional ability to extract scatter distribution information based on the observed width of the detected spots. This paper describes experiments done at a synchrotron facility investigating the use of a Shack–Hartmann system for biomedical applications and include our method and examples of scatter contrast extraction from the method. [ABSTRACT FROM AUTHOR]

Published

2015

4. Design of a mouse restraint for synchrotron-based computed tomography imaging.

Author

Gagnon, Kenneth B., Caine, Sally, Samadi, Nazanin, Martinson, Mercedes, van der Loop, Melanie, Alcorn, Jane, Chapman, L. Dean, Belev, George, and Nichol, Helen

Subjects

COMPUTED tomography, SYNCHROTRON radiation, ANESTHESIA, MICE, ANIMAL models in research

Abstract

High-resolution computed tomography (CT) imaging of a live animal within a lead-lined synchrotron light hutch presents several unique challenges. In order to confirm that the animal is under a stable plane of anaesthesia, several physiological parameters ( e.g. heart rate, arterial oxygen saturation, core body temperature and respiratory rate) must be remotely monitored from outside the imaging hutch. In addition, to properly scan the thoracic region using CT, the animal needs to be held in a vertical position perpendicular to the fixed angle of the X-ray beam and free to rotate 180°-360°. A new X-ray transparent mouse restraint designed and fabricated using computer-aided design software and three-dimensional rapid prototype printing has been successfully tested at the Biomedical Imaging and Therapy bending-magnet (BMIT-BM) beamline at the Canadian Light Source. [ABSTRACT FROM AUTHOR]

Published

2015

5. Biomedical Imaging Using Synchrotron Radiation: Experience at the Biomedical Imaging and Therapy (BMIT) Facility at the Canadian Light Source.

Author

Wiebe, Sheldon, Wysokinski, Tomasz W., Belev, George, Miller, Denise, Webb, Adam, Zhu, Ning, Cooper, David, Izadifar, Zohreh, Panahifar, Arash, Samadi, Nazanin, Martinson, Mercedes, Ford, Nancy L., Deman, Pierre, Luan, Xiaojie, Ianowski, Juan P., Chen, Daniel, and Chapman, Dean

Subjects

DIAGNOSTIC imaging, THERAPEUTIC use of electron beams, SYNCHROTRON radiation sources, SYNCHRONOUS accelerators, PHASE contrast magnetic resonance imaging, LIGHT absorption, CANADIAN Light Source (Saskatoon, Sask.)

Abstract

The Biomedical Imaging and Therapy (BMIT) beamlines at the Canadian Light Source (CLS) comprise a multi-modality synchrotron imaging facility capable of imaging objects with 2–200 μm resolution with beam sizes up to ~200 mm wide and ~10 mm high in the experimental hutches [1–3]. BMIT hosts two beamlines, a bend magnet 05B1-1 and an insertion device 05ID-2, with capabilities to apply absorption imaging, in-line phase contrast imaging (PCI), analyzer-based imaging (ABI) or diffraction-enhanced imaging (DEI), and K-Edge Subtraction (KES) imaging. Talbot or grating interferometry is under development. [ABSTRACT FROM PUBLISHER]

Published

2015

6. A phase-space beam position monitor for synchrotron radiation.

Author

Samadi, Nazanin, Bassey, Bassey, Martinson, Mercedes, Belev, George, Dallin, Les, de Jong, Mark, and Chapman, Dean

Subjects

SYNCHROTRON radiation, PHOTON beams, ELECTRON beams, MAGNETIC fields, X-ray diffraction

Abstract

The stability of the photon beam position on synchrotron beamlines is critical for most if not all synchrotron radiation experiments. The position of the beam at the experiment or optical element location is set by the position and angle of the electron beam source as it traverses the magnetic field of the bend-magnet or insertion device. Thus an ideal photon beam monitor would be able to simultaneously measure the photon beam's position and angle, and thus infer the electron beam's position in phase space. X-ray diffraction is commonly used to prepare monochromatic beams on X-ray beamlines usually in the form of a double-crystal monochromator. Diffraction couples the photon wavelength or energy to the incident angle on the lattice planes within the crystal. The beam from such a monochromator will contain a spread of energies due to the vertical divergence of the photon beam from the source. This range of energies can easily cover the absorption edge of a filter element such as iodine at 33.17 keV. A vertical profile measurement of the photon beam footprint with and without the filter can be used to determine the vertical centroid position and angle of the photon beam. In the measurements described here an imaging detector is used to measure these vertical profiles with an iodine filter that horizontally covers part of the monochromatic beam. The goal was to investigate the use of a combined monochromator, filter and detector as a phase-space beam position monitor. The system was tested for sensitivity to position and angle under a number of synchrotron operating conditions, such as normal operations and special operating modes where the photon beam is intentionally altered in position and angle at the source point. The results are comparable with other methods of beam position measurement and indicate that such a system is feasible in situations where part of the synchrotron beam can be used for the phase-space measurement. [ABSTRACT FROM AUTHOR]

Published

2015

7. Phase-preserving beam expander for biomedical X-ray imaging.

Author

Martinson, Mercedes, Samadi, Nazanin, Bassey, Bassey, Gomez, Ariel, and Chapman, Dean

Subjects

*MEDICAL imaging systems, *PHASE transitions, *BEAM optics, *BIOMEDICAL materials, *X-ray imaging, *MONOCHROMATORS, *EXPERIMENTS

Abstract

The BioMedical Imaging and Therapy beamlines at the Canadian Light Source are used by many researchers to capture phase-based imaging data. These experiments have so far been limited by the small vertical beam size, requiring vertical scanning of biological samples in order to image their full vertical extent. Previous work has been carried out to develop a bent Laue beam-expanding monochromator for use at these beamlines. However, the first attempts exhibited significant distortion in the diffraction plane, increasing the beam divergence and eliminating the usefulness of the monochromator for phase-related imaging techniques. Recent work has been carried out to more carefully match the polychromatic and geometric focal lengths in a so-called `magic condition' that preserves the divergence of the beam and enables full-field phase-based imaging techniques. The new experimental parameters, namely asymmetry and Bragg angles, were evaluated by analysing knife-edge and in-line phase images to determine the effect on beam divergence in both vertical and horizontal directions, using the flat Bragg double-crystal monochromator at the beamline as a baseline. The results show that by using the magic condition, the difference between the two monochromator types is less than 10% in the diffraction plane. Phase fringes visible in test images of a biological sample demonstrate that this difference is small enough to enable in-line phase imaging, despite operating at a sub-optimal energy for the wafer and asymmetry angle that was used. [ABSTRACT FROM AUTHOR]

Published

2015

8. Development of a bent Laue beam-expanding double-crystal monochromator for biomedical X-ray imaging.

Author

Martinson, Mercedes, Samadi, Nazanin, Belev, George, Bassey, Bassey, Lewis, Rob, Aulakh, Gurpreet, and Chapman, Dean

Subjects

*MONOCHROMATORS, *X-rays, *CATHODE rays, *VACUUM tubes, *ELECTROMAGNETIC waves

Abstract

The Biomedical Imaging and Therapy (BMIT) beamline at the Canadian Light Source has produced some excellent biological imaging data. However, the disadvantage of a small vertical beam limits its usability in some applications. Micro-computed tomography (micro-CT) imaging requires multiple scans to produce a full projection, and certain dynamic imaging experiments are not possible. A larger vertical beam is desirable. It was cost-prohibitive to build a longer beamline that would have produced a large vertical beam. Instead, it was proposed to develop a beam expander that would create a beam appearing to originate at a source much farther away. This was accomplished using a bent Laue double-crystal monochromator in a non-dispersive divergent geometry. The design and implementation of this beam expander is presented along with results from the micro-CT and dynamic imaging tests conducted with this beam. Flux (photons per unit area per unit time) has been measured and found to be comparable with the existing flat Bragg double-crystal monochromator in use at BMIT. This increase in overall photon count is due to the enhanced bandwidth of the bent Laue configuration. Whilst the expanded beam quality is suitable for dynamic imaging and micro-CT, further work is required to improve its phase and coherence properties. [ABSTRACT FROM AUTHOR]

Published

2014

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

Author

Martinson, Mercedes and Chapman, Dean

Subjects

*CRYSTALS, *MONOCHROMATORS, *COHERENCE (Nuclear physics), *CRYSTALLOGRAPHY, *OPTICAL instruments

Abstract

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 ±1° or ±5 keV. [ABSTRACT FROM AUTHOR]

Published

2016