Effect of tomography resolution on the calculated microscopic properties of porous materials: comparison of sandstone and carbonate rocks

Reza Gooya; Stefan Bruns; Dirk Müter; Arash Moaddel Haghighi; Ralph Patrick Harti; Susan Louise Svane Stipp; Henning Osholm Sørensen

doi:10.1063/1.4962389

Effect of tomography resolution on the calculated microscopic properties of porous materials: comparison of sandstone and carbonate rocks

Reza Gooya, Stefan Bruns, Dirk Müter, Arash Moaddel Haghighi, Ralph Patrick Harti, Susan Louise Svane Stipp, Henning Osholm Sørensen

Department of Chemistry

18 Citations (Scopus)

111 Downloads (Pure)

Abstract

X-ray computed tomography is useful for providing insight into the internal structure of porous materials. Extracting reliable quantitative information is difficult because the derived properties rely heavily on data resolution, i.e., very different values emerge, depending on the relationship between size of the features in the sample and the resolution of the 3D tomograms. Here, we present a method for testing if resolution is sufficient for determining reliable petrophysical parameters, i.e., with low levels of uncertainty. We derived the physical properties of sandstone and carbonate rocks over a range of voxel dimensions by computationally reducing raw data resolution in our high resolution images. Lower resolution decreases the calculated surface area for all samples and increases the derived permeability for sandstone. The permeability vs change in resolution was not monotonic for carbonates. The differences in trends for the two rock types result from different pore sizes and pore size distributions.

Original language	English
Article number	104102
Journal	Applied Physics Letters
Volume	109
Issue number	10
Number of pages	4
ISSN	0003-6951
DOIs	https://doi.org/10.1063/1.4962389
Publication status	Published - 5 Sept 2016

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abstract = "X-ray computed tomography is useful for providing insight into the internal structure of porous materials. Extracting reliable quantitative information is difficult because the derived properties rely heavily on data resolution, i.e., very different values emerge, depending on the relationship between size of the features in the sample and the resolution of the 3D tomograms. Here, we present a method for testing if resolution is sufficient for determining reliable petrophysical parameters, i.e., with low levels of uncertainty. We derived the physical properties of sandstone and carbonate rocks over a range of voxel dimensions by computationally reducing raw data resolution in our high resolution images. Lower resolution decreases the calculated surface area for all samples and increases the derived permeability for sandstone. The permeability vs change in resolution was not monotonic for carbonates. The differences in trends for the two rock types result from different pore sizes and pore size distributions.",

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T1 - Effect of tomography resolution on the calculated microscopic properties of porous materials

T2 - comparison of sandstone and carbonate rocks

AU - Gooya, Reza

AU - Bruns, Stefan

AU - Müter, Dirk

AU - Moaddel Haghighi, Arash

AU - Harti, Ralph Patrick

AU - Stipp, Susan Louise Svane

AU - Sørensen, Henning Osholm

PY - 2016/9/5

Y1 - 2016/9/5

N2 - X-ray computed tomography is useful for providing insight into the internal structure of porous materials. Extracting reliable quantitative information is difficult because the derived properties rely heavily on data resolution, i.e., very different values emerge, depending on the relationship between size of the features in the sample and the resolution of the 3D tomograms. Here, we present a method for testing if resolution is sufficient for determining reliable petrophysical parameters, i.e., with low levels of uncertainty. We derived the physical properties of sandstone and carbonate rocks over a range of voxel dimensions by computationally reducing raw data resolution in our high resolution images. Lower resolution decreases the calculated surface area for all samples and increases the derived permeability for sandstone. The permeability vs change in resolution was not monotonic for carbonates. The differences in trends for the two rock types result from different pore sizes and pore size distributions.

AB - X-ray computed tomography is useful for providing insight into the internal structure of porous materials. Extracting reliable quantitative information is difficult because the derived properties rely heavily on data resolution, i.e., very different values emerge, depending on the relationship between size of the features in the sample and the resolution of the 3D tomograms. Here, we present a method for testing if resolution is sufficient for determining reliable petrophysical parameters, i.e., with low levels of uncertainty. We derived the physical properties of sandstone and carbonate rocks over a range of voxel dimensions by computationally reducing raw data resolution in our high resolution images. Lower resolution decreases the calculated surface area for all samples and increases the derived permeability for sandstone. The permeability vs change in resolution was not monotonic for carbonates. The differences in trends for the two rock types result from different pore sizes and pore size distributions.

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Effect of tomography resolution on the calculated microscopic properties of porous materials: comparison of sandstone and carbonate rocks

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