Fluid transport in glass beads phantoms: Spatial velocity measurements and confirmation of the stochastic model

M. Bencsik; B. Issa; M. A. Al-Mugheiry; R. W. Bowtell; P. Mansfield

doi:10.1016/S0730-725X(98)00044-7

Fluid transport in glass beads phantoms: Spatial velocity measurements and confirmation of the stochastic model

M. Bencsik, B. Issa, M. A. Al-Mugheiry, R. W. Bowtell, P. Mansfield

Research output: Contribution to journal › Article › peer-review

1 Citation (Scopus)

Abstract

A stochastic model of fluid flow in porous rocks has been previously developed to explain the measured distribution of local velocity. The theoretical predictions Of this model agree well with experimental results obtained from the magnetic resonance imaging-based measurements of the spatial variation of velocity of water permeating through Bentheimer and Clashach sandstones. To further verify previous results, we have performed new velocity measurement experiments using an efficient velocity encoded π- echo planar imaging sequence on glass bead phantoms that exhibit more regular pore size distribution than rocks. The results show that velocity distributions in glass bead phantoms also exhibit Gaussian profiles and the linear relationship between the velocity variance and the mean velocity (the Mansfield-Issa equation).

Original language	English
Pages (from-to)	605-607
Number of pages	3
Journal	Magnetic Resonance Imaging
Volume	16
Issue number	5-6
DOIs	https://doi.org/10.1016/S0730-725X(98)00044-7
Publication status	Published - Jun 1998
Externally published	Yes

Keywords

Glass beads
π-echo planar imaging

ASJC Scopus subject areas

Biophysics
Biomedical Engineering
Radiology Nuclear Medicine and imaging

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10.1016/S0730-725X(98)00044-7

Cite this

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title = "Fluid transport in glass beads phantoms: Spatial velocity measurements and confirmation of the stochastic model",

abstract = "A stochastic model of fluid flow in porous rocks has been previously developed to explain the measured distribution of local velocity. The theoretical predictions Of this model agree well with experimental results obtained from the magnetic resonance imaging-based measurements of the spatial variation of velocity of water permeating through Bentheimer and Clashach sandstones. To further verify previous results, we have performed new velocity measurement experiments using an efficient velocity encoded π- echo planar imaging sequence on glass bead phantoms that exhibit more regular pore size distribution than rocks. The results show that velocity distributions in glass bead phantoms also exhibit Gaussian profiles and the linear relationship between the velocity variance and the mean velocity (the Mansfield-Issa equation).",

keywords = "Glass beads, π-echo planar imaging",

author = "M. Bencsik and B. Issa and Al-Mugheiry, {M. A.} and Bowtell, {R. W.} and P. Mansfield",

year = "1998",

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T2 - Spatial velocity measurements and confirmation of the stochastic model

AU - Bencsik, M.

AU - Issa, B.

AU - Al-Mugheiry, M. A.

AU - Bowtell, R. W.

AU - Mansfield, P.

PY - 1998/6

Y1 - 1998/6

N2 - A stochastic model of fluid flow in porous rocks has been previously developed to explain the measured distribution of local velocity. The theoretical predictions Of this model agree well with experimental results obtained from the magnetic resonance imaging-based measurements of the spatial variation of velocity of water permeating through Bentheimer and Clashach sandstones. To further verify previous results, we have performed new velocity measurement experiments using an efficient velocity encoded π- echo planar imaging sequence on glass bead phantoms that exhibit more regular pore size distribution than rocks. The results show that velocity distributions in glass bead phantoms also exhibit Gaussian profiles and the linear relationship between the velocity variance and the mean velocity (the Mansfield-Issa equation).

AB - A stochastic model of fluid flow in porous rocks has been previously developed to explain the measured distribution of local velocity. The theoretical predictions Of this model agree well with experimental results obtained from the magnetic resonance imaging-based measurements of the spatial variation of velocity of water permeating through Bentheimer and Clashach sandstones. To further verify previous results, we have performed new velocity measurement experiments using an efficient velocity encoded π- echo planar imaging sequence on glass bead phantoms that exhibit more regular pore size distribution than rocks. The results show that velocity distributions in glass bead phantoms also exhibit Gaussian profiles and the linear relationship between the velocity variance and the mean velocity (the Mansfield-Issa equation).

KW - Glass beads

KW - π-echo planar imaging

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Fluid transport in glass beads phantoms: Spatial velocity measurements and confirmation of the stochastic model

Abstract

Keywords

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