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Main Authors: Manni, Mathieu, Ben-Yehuda, Adi, Klein, Yishay, Lukic, Bratislav, Kingston, Andrew, Rack, Alexander, Shwartz, Sharon, Viganò, Nicola
Format: Preprint
Published: 2023
Subjects:
Online Access:https://arxiv.org/abs/2306.16258
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author Manni, Mathieu
Ben-Yehuda, Adi
Klein, Yishay
Lukic, Bratislav
Kingston, Andrew
Rack, Alexander
Shwartz, Sharon
Viganò, Nicola
author_facet Manni, Mathieu
Ben-Yehuda, Adi
Klein, Yishay
Lukic, Bratislav
Kingston, Andrew
Rack, Alexander
Shwartz, Sharon
Viganò, Nicola
contents X-ray Fluorescence Ghost Imaging (XRF-GI) was recently demonstrated for x-ray lab sources. It has the potential to reduce acquisition time and deposited dose by choosing their trade-off with spatial resolution, while alleviating the focusing constraints of the probing beam. Here, we demonstrate the realization of synchrotron-based XRF-GI: We present both an adapted experimental setup and its corresponding required computational technique to process the data. This extends the above-mentioned potential advantages of GI to synchrotron XRF imaging. In addition, it enables new strategies to improve resilience against drifts at all scales, and the study of previously inaccessible samples, such as liquids.
format Preprint
id arxiv_https___arxiv_org_abs_2306_16258
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Synchrotron-based X-ray Fluorescence Ghost Imaging
Manni, Mathieu
Ben-Yehuda, Adi
Klein, Yishay
Lukic, Bratislav
Kingston, Andrew
Rack, Alexander
Shwartz, Sharon
Viganò, Nicola
Optics
Accelerator Physics
X-ray Fluorescence Ghost Imaging (XRF-GI) was recently demonstrated for x-ray lab sources. It has the potential to reduce acquisition time and deposited dose by choosing their trade-off with spatial resolution, while alleviating the focusing constraints of the probing beam. Here, we demonstrate the realization of synchrotron-based XRF-GI: We present both an adapted experimental setup and its corresponding required computational technique to process the data. This extends the above-mentioned potential advantages of GI to synchrotron XRF imaging. In addition, it enables new strategies to improve resilience against drifts at all scales, and the study of previously inaccessible samples, such as liquids.
title Synchrotron-based X-ray Fluorescence Ghost Imaging
topic Optics
Accelerator Physics
url https://arxiv.org/abs/2306.16258