Chemical element mapping by x-ray computational ghost fluorescence

Klein, Yishay; Sefi, O.; Schwartz, Hila; Shwartz, Sharon

doi:10.1364/optica.441682

Cited by 17 publications

(10 citation statements)

References 51 publications

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“…This agrees with the width of the measured autocorrelation function Extended Data Fig. 4 and indicates that further improvement of the spatial resolution is feasible by a simple reduction of the speckle size 34 . As shown in Extended Data Fig.…”

Section: Extended Data Experiments At Lower Photon Energysupporting

confidence: 87%

“…This is because in CGI the spatial information is derived from the spatially modulated beam, which interacts with the object, rather than from the detector pixels. While X-ray CGI has been demonstrated with transmitted [30][31][32][33] , fluorescent 34 , and refracted radiation 35 , we apply it to incoherent scattered radiation.…”

mentioning

confidence: 99%

“…It is worth mentioning that although cameras based on the Compton effect are available (34,35), their resolution is poor due to the tendency of scattered radiation to blur. As a result, they are not suitable for medical imaging, unlike our proposed method which provides higher resolution and better image quality (35,36).…”

mentioning

confidence: 99%

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High-resolution computed tomography with scattered X-ray radiation and a single pixel detector

Shwartz,

Yehuda,

Sefi

et al. 2023

Preprint

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X-ray imaging is a prevalent technique for non-invasively visualizing the interior of the human body and opaque instruments. In most commercial X-ray modalities, an image is formed by measuring the X-rays that pass through the object of interest. However, despite the potential of scattered radiation to provide additional information about the object, it is often disregarded due to its inherent tendency to cause blurring. Consequently, conventional imaging modalities do not measure or utilize these valuable data. In contrast, we propose and experimentally demonstrate a high-resolution technique for X-ray computed tomography (CT) that measures scattered radiation by exploiting computational ghost imaging (CGI). We show that our method can provide sub-200 µm resolution, exceeding the capabilities of most existing X-ray imaging modalities. Our research reveals a promising technique for incorporating scattered radiation data in CT scans to improve image resolution and minimize radiation exposure for patients. The findings of our study suggest that our technique could represent a significant advancement in the fields of medical and industrial imaging, with the potential to enhance the accuracy and safety of diagnostic imaging procedures.

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Section: Extended Data Experiments At Lower Photon Energysupporting

confidence: 87%

mentioning

confidence: 99%

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High-resolution computed tomography with scattered X-ray radiation and a single pixel detector

Shwartz,

Yehuda,

Sefi

et al. 2023

Preprint

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“…These patterns are used to form a reconstructed image through correlation calculation. Owing to its wide range of light sources and strong anti-interference ability, GI has attracted significant attention in several related fields such as X-ray imaging 1 , 2 , terahertz imaging 3 , acoustic imaging 4 , three-dimensional imaging 5 , 6 , fluorescence imaging 1 , optical encryption 7 , 8 , and underwater imaging 9 – 15 . The application scenarios and influencing factors of GI are depicted in Fig.…”

Section: Introductionmentioning

confidence: 99%

A ghost imaging framework based on laser mode speckle pattern for underwater environments

Yang,

Wang,

et al. 2024

Commun Eng

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Due to the complex physical processes found in underwater environments, such as absorption, scattering, and noise, it is challenging to obtain high-quality images using conventional camera-based imaging techniques. Ghost imaging possesses strong anti-interference capabilities and can effectively obtain images in underwater environments. Here, we propose a ghost imaging framework based on a physical model of M2-ordered laser mode patterns and apply it to Ghost Imaging. The simulation results show that the Laser Mode Speckle Ghost Imaging can reconstruct the overall trapped contour even at a low sampling rate, specifically below 0.64%. A high-quality image with a Peak Signal-to-Noise Ratio of 19 dB can be achieved using the Laser Mode Speckle Ghost Imaging when the sampling rate is 5%. Even with a relative random noise of 1.0%–5.0%, the imaging quality of Laser Mode Speckle Ghost Imaging is superior to that of Random speckle pattern Ghost Imaging, Walsh speckle pattern Ghost Imaging, and Haar speckle pattern Ghost Imaging when the sampling rate consistent. Our experimental results in a turbid water environment confirm the conclusions drawn from the simulation results. The proposed Laser Mode Speckle Ghost Imaging can be used as an imaging solution in challenging liquid environments, such as turbid liquids, inclement weather, and biological tissue fluids.

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“…The comparison of the imaging qualities of orthogonal and random speckle patterns in air 13 has shown that orthogonal speckle patterns are more suitable for low-sampling CGI. Owing to its wide range of light sources and strong antiinterference ability, GI has attracted significant attention in several related fields such as X-ray imaging 14,15 , terahertz imaging 16 , acoustic imaging 17 , three-dimensional imaging 18,19 , fluorescence imaging 14 , optical encryption 20,21 , and underwater imaging [22][23][24][25][26][27] . Application scenarios and influencing factors of GI are shown in Fig.…”

mentioning

confidence: 99%

Laser mode speckle ghost imaging of underwater environments

Feng

Yang²,

Wu³

et al. 2023

Preprint

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Absorption, scattering, noise, and low-sensitivity detector lead to poor quality in conventional underwater imaging. In response, Ghost imaging (GI) has emerged as an effective anti-interference underwater imaging method based on the relationship between illumination speckle patterns and a non-spatial-resolution detector. Conventional speckle patterns are distributed based on mathematical models such as the random, Hadamard, or Walsh models. In this study, we apply novel speckle patterns based on a physical model of M2 ordered laser modes to GI. The laser mode speckle pattern GI (LMS-GI) system achieves perfect imaging quality at a sampling rate of 5% or less; good imaging quality persists even below 0.64%. Despite relative random noise of 1.0%~ 5.0%, it outperforms the other GIs. Furthermore, at a low sampling rate of 2.48%, LMS-GI is effective not only in inclement weather, but also in complex liquid environments such as turbid liquids and biological tissue fluids.

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Chemical element mapping by x-ray computational ghost fluorescence

Cited by 17 publications

References 51 publications

High-resolution computed tomography with scattered X-ray radiation and a single pixel detector

High-resolution computed tomography with scattered X-ray radiation and a single pixel detector

A ghost imaging framework based on laser mode speckle pattern for underwater environments

Laser mode speckle ghost imaging of underwater environments

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