Continuous porosity characterization: Metric-scale intervals in heterogeneous sedimentary rocks using medical CT-scanner

Larmagnat, S; Roches, Mathieu Des; Daigle, Louis-Frédéric; Francus, Pierre; Lavoie, Denis; Raymond, Jasmin; Malo, Michel; Aubiès-Trouilh, Alexandre

doi:10.1016/j.marpetgeo.2019.04.039

Cited by 14 publications

(4 citation statements)

References 89 publications

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“…A possible improvement of this stoichiometric method could reside in increasing the exposure time or to acquire repeated scans in order to improve the signal‐to‐noise ratio (e.g., Larmagnat et al., 2019), especially when very dense minerals, reducing the number of photons reaching the detectors, are present.…”

Section: Discussionmentioning

confidence: 99%

Identification of Common Minerals Using Stoichiometric Calibration Method for Dual‐Energy CT

Martini

Francus

Trotta

et al. 2021

Geochem Geophys Geosyst

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X-ray computed tomography (CT) is a non-destructive technique allowing the visualization of sample internal structure. A medical CT scanner consists in an X-ray source and a detector, which face each other and rotate around the sample. Bi-dimensional radiographic projections are acquired at various angles from 0° to 360° and then processed by a mathematical algorithm (i.e., image reconstruction) in order to obtain a 3D visualization of the object. Different types of image reconstructions exist, including the widely used filtered backprojection that requires little computational resources but produces less qualitatively accurate images, and iterative reconstruction, based on time consuming and numerically intensive algorithm but providing better images quality (Bushberg et al., 2012).The images are displayed in a gray scale related to the X-ray attenuation by the sample materials (Rizescu et al., 2001).Initially, this technology was developed for medical imaging, but its potential for other domains was rapidly understood (Mees et al., 2003).This paper explores a specific CT methodology, called dual-energy CT scanning (DECT), elaborated for the first time in the seventies by Alvarez and Makovski (1976). The technique consists in imaging objects with two different X-ray spectra and in combining the results to achieve various objectives, including one allowing the discrimination and identification of materials based on their density and elemental composition. From a physical perspective, DECT exploits the energy dependence of photoelectric absorption and Compton scattering

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Section: Discussionmentioning

confidence: 99%

Identification of Common Minerals Using Stoichiometric Calibration Method for Dual‐Energy CT

Martini

Francus

Trotta

et al. 2021

Geochem Geophys Geosyst

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“…The X-ray tube can be operated in the range of 70-140 kVp. This platform is used for several non-medical applications, including material characterization with dual-energy techniques Fortin et al (2013); Larmagnat et al (2019); Martini et al (2021); Di Schiavi Trotta et al (2022).…”

Section: Working With Proprietary Formatmentioning

confidence: 99%

Tomographic reconstruction strategies for nondestructive testing with a commercial CT scanner

Di Schiavi Trotta,

Matenine,

Lemaréchal

et al. 2023

Front. Earth Sci.

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In this work, a framework was developed to access and process raw data from a commercial X-ray Computed Tomography (CT) scanner for research purposes. Our method requires vendor-provided binaries to convert the data to a readable format and also to remove the effect of proprietary beam hardening preprocessing. As a result, custom reconstruction techniques, including beam-hardening corrections algorithms, can be applied. Small region-of-interest CT imaging techniques and different backprojection algorithms were investigated to improve image quality (spatial resolution, noise) with an in-house iterative reconstruction algorithm. For a reconstruction matrix of 512 pixels × 512 pixels, processing times of approximately 2.5 s per slice were obtained using a set of 8 x GPUs. With this framework, high-quality images of high density samples (e.g., minerals) can be obtained with reduced truncation-induced blurring, free of artifacts stemming from the reconstruction process and reduced beam-hardening artifacts.

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“…Furthermore, the acquisition of high-Z and high density samples with reduced artifacts is also advantageous in the field of geology, such as porosity characterization in rocks with a CT scanner [31]. The presented algorithm can potentially deal with low and highly attenuation materials, such as water and dense rocks, improving the desired characterization by removing the bias caused by beam-hardening artifacts.…”

Section: Real Samples Applicationmentioning

confidence: 99%

Beam-hardening corrections through a polychromatic projection model integrated to an iterative reconstruction algorithm

Trotta

Matenine

Martini

et al. 2022

NDT & E International

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Continuous porosity characterization: Metric-scale intervals in heterogeneous sedimentary rocks using medical CT-scanner

Cited by 14 publications

References 89 publications

Identification of Common Minerals Using Stoichiometric Calibration Method for Dual‐Energy CT

Identification of Common Minerals Using Stoichiometric Calibration Method for Dual‐Energy CT

Tomographic reconstruction strategies for nondestructive testing with a commercial CT scanner

Beam-hardening corrections through a polychromatic projection model integrated to an iterative reconstruction algorithm

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