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Main Authors: John, Dominik, Chen, Junan, Gaßner, Christoph, Savatović, Sara, Petzold, Lisa Marie, Wirtensohn, Sami, Riedel, Mirko, Hammel, Jörg U., Moosmann, Julian, Beckmann, Felix, Wieczorek, Matthias, Herzen, Julia
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2408.00482
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author John, Dominik
Chen, Junan
Gaßner, Christoph
Savatović, Sara
Petzold, Lisa Marie
Wirtensohn, Sami
Riedel, Mirko
Hammel, Jörg U.
Moosmann, Julian
Beckmann, Felix
Wieczorek, Matthias
Herzen, Julia
author_facet John, Dominik
Chen, Junan
Gaßner, Christoph
Savatović, Sara
Petzold, Lisa Marie
Wirtensohn, Sami
Riedel, Mirko
Hammel, Jörg U.
Moosmann, Julian
Beckmann, Felix
Wieczorek, Matthias
Herzen, Julia
contents Recent advances in propagation-based phase-contrast imaging, such as hierarchical imaging, have enabled the visualization of internal structures in large biological specimens and material samples. However, modulation-based techniques, which provide quantitative electron density information, face challenges when imaging larger objects due to stringent beam stability requirements and detector distortions. Extending the field of view of these methods is crucial for obtaining comparable quantitative results across beamlines and adapting to the smaller beam profiles of fourth-generation synchrotron sources. We introduce a novel image processing technique combining an eigenflat optimization with deformable image registration to address the challenges and enable quantitative high-resolution scans of centimeter-sized objects with multiple-micrometer resolution. We demonstrate the potential of the method by obtaining an electron density map of a rat brain sample 15 mm in diameter despite the limited horizontal field of view of 6 mm of the beamline. This showcases the technique's ability to significantly widen the range of applications of modulation-based techniques in both biological and materials science research.
format Preprint
id arxiv_https___arxiv_org_abs_2408_00482
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Extending the field of view in modulation-based X-ray phase microtomography
John, Dominik
Chen, Junan
Gaßner, Christoph
Savatović, Sara
Petzold, Lisa Marie
Wirtensohn, Sami
Riedel, Mirko
Hammel, Jörg U.
Moosmann, Julian
Beckmann, Felix
Wieczorek, Matthias
Herzen, Julia
Medical Physics
Optics
Recent advances in propagation-based phase-contrast imaging, such as hierarchical imaging, have enabled the visualization of internal structures in large biological specimens and material samples. However, modulation-based techniques, which provide quantitative electron density information, face challenges when imaging larger objects due to stringent beam stability requirements and detector distortions. Extending the field of view of these methods is crucial for obtaining comparable quantitative results across beamlines and adapting to the smaller beam profiles of fourth-generation synchrotron sources. We introduce a novel image processing technique combining an eigenflat optimization with deformable image registration to address the challenges and enable quantitative high-resolution scans of centimeter-sized objects with multiple-micrometer resolution. We demonstrate the potential of the method by obtaining an electron density map of a rat brain sample 15 mm in diameter despite the limited horizontal field of view of 6 mm of the beamline. This showcases the technique's ability to significantly widen the range of applications of modulation-based techniques in both biological and materials science research.
title Extending the field of view in modulation-based X-ray phase microtomography
topic Medical Physics
Optics
url https://arxiv.org/abs/2408.00482