Opportunities for Characterizing Geological Flows Using Magnetic Resonance Imaging

Lev, Einat; Boyce, Christopher M.

doi:10.1016/j.isci.2020.101534

Cited by 9 publications

(7 citation statements)

References 103 publications

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“…8 It is apparent there is truly interdisciplinary crosstalk at the junction of these fields, not specifically just when considering quinones, but also thinking about understanding complex flow scenarios in the human body, in the environment, and in this case, in electrochemical cells. Scientists are beginning to make these connections 9 and trying to work together to understand unique applications, all of which have some sort of engineering insights at their core.…”

Section: Go With the Fluorescent Flowmentioning

confidence: 99%

Go with the fluorescent flow

Muzzio

2021

Joule

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Section: Go With the Fluorescent Flowmentioning

confidence: 99%

Go with the fluorescent flow

Muzzio

2021

Joule

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“…MRI was first designed to map geological features beneath the surface of Earth. Through non-invasive visualization of interior anatomy, early illness identification, and surgical intervention guidance, this interdisciplinary synergy has revolutionized diagnostic medicine [ 24 ].…”

Section: Introductionmentioning

confidence: 99%

Exploring the Intersection of Geophysics and Diagnostic Imaging in the Health Sciences

Singh,

Nayak,

Behl

et al. 2024

Diagnostics

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To develop diagnostic imaging approaches, this paper emphasizes the transformational potential of merging geophysics with health sciences. Diagnostic imaging technology improvements have transformed the health sciences by enabling earlier and more precise disease identification, individualized therapy, and improved patient care. This review article examines the connection between geophysics and diagnostic imaging in the field of health sciences. Geophysics, which is typically used to explore Earth’s subsurface, has provided new uses of its methodology in the medical field, providing innovative solutions to pressing medical problems. The article examines the different geophysical techniques like electrical imaging, seismic imaging, and geophysics and their corresponding imaging techniques used in health sciences like tomography, magnetic resonance imaging, ultrasound imaging, etc. The examination includes the description, similarities, differences, and challenges associated with these techniques and how modified geophysical techniques can be used in imaging methods in health sciences. Examining the progression of each method from geophysics to medical imaging and its contributions to illness diagnosis, treatment planning, and monitoring are highlighted. Also, the utilization of geophysical data analysis techniques like signal processing and inversion techniques in image processing in health sciences has been briefly explained, along with different mathematical and computational tools in geophysics and how they can be implemented for image processing in health sciences. The key findings include the development of machine learning and artificial intelligence in geophysics-driven medical imaging, demonstrating the revolutionary effects of data-driven methods on precision, speed, and predictive modeling.

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“…It is, therefore, necessary to examine how backfill slurry flows change with vertical pipe depth and to monitor flow parameters by adopting some investigative tools. Currently, a range of techniques, including optical methods [13,14], X-ray or gammaray scanning [15,16] and nuclear magnetic resonance imaging (MRI) [17,18] are applied to measure fluid flows. However, each of these techniques has its advantages and inherent limitations.…”

Section: Introductionmentioning

confidence: 99%

“…This paper intends to evaluate the flow behavior of paste slurry transported by gravity flow. Two L-shaped pipeline systems with ERT were designed and manufactured to visualize flow regimes and measure the axial velocity and pipe pressure of paste slurry in Currently, a range of techniques, including optical methods [13,14], X-ray or gammaray scanning [15,16] and nuclear magnetic resonance imaging (MRI) [17,18] are applied to measure fluid flows. However, each of these techniques has its advantages and inherent limitations.…”

Section: Introductionmentioning

confidence: 99%

Experimental Investigation on Flow Behavior of Paste Slurry Transported by Gravity in Vertical Pipes

Jian-dong

Wang

et al. 2022

Processes

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In order to dispose of large quantities of mineral tailings, paste backfill is proposed and widely adopted. Paste backfill, which has high concentration and yield stress and behaves as a non-Newtonian fluid, is prepared at the surface plant and then transported underground. Vertical pipelines are more likely to suffer various failures, such as pipe breaks, wear and plugging, during the transport process. Few present studies focus on the flow behavior of paste slurry flowing in vertical pipes. In this work, two L-shaped pipeline systems with internal diameters (ID) of 40 mm and 65 mm with electrical resistance tomography (ERT) were manufactured to visualize flow regimes and measure the axial velocity and pipe pressure of slurry flowing in the upper and lower zones of vertical pipes. Flow regimes were extracted from ERT-reconstructed images stacked by time-series. Based on this, four typical flow regimes were summarized, and the characteristics of velocity and pressure change with vertical pipe depth were discussed.

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Opportunities for Characterizing Geological Flows Using Magnetic Resonance Imaging

Cited by 9 publications

References 103 publications

Go with the fluorescent flow

Go with the fluorescent flow

Exploring the Intersection of Geophysics and Diagnostic Imaging in the Health Sciences

Experimental Investigation on Flow Behavior of Paste Slurry Transported by Gravity in Vertical Pipes

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