Characterizing soil macroporosity by X-ray microfocus computed tomography and quantification of the coring damages.

Characterizing soil macroporosity by X-ray microfocus computed tomography and quantification of the coring damages.

X-ray Computed Tomography (X-ray µCT) was employed to characterize vertical variations of structural porosity of a soil profile (pore dimension higher than 5.103 µm3). Three distinct horizons of a Cambisol have been studied for a total depth of 75 cm: L, S1/S2 and S2/SFe horizons. Samples have b...

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Main Authors: Caner L., Sardini P., Robinet J.C., Hubert F., Gallier J.
Format: Article
Language:English
Published: EDP Sciences 2010-06-01
Series:EPJ Web of Conferences
Online Access:http://dx.doi.org/10.1051/epjconf/20100622023
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spelling doaj-ec6ea05f30cf4f04a11aef2aad0bfc462021-08-02T04:59:16ZengEDP SciencesEPJ Web of Conferences2100-014X2010-06-0162202310.1051/epjconf/20100622023Characterizing soil macroporosity by X-ray microfocus computed tomography and quantification of the coring damages.Caner L.Sardini P.Robinet J.C.Hubert F.Gallier J.X-ray Computed Tomography (X-ray µCT) was employed to characterize vertical variations of structural porosity of a soil profile (pore dimension higher than 5.103 µm3). Three distinct horizons of a Cambisol have been studied for a total depth of 75 cm: L, S1/S2 and S2/SFe horizons. Samples have been cored in situ by driving in PVC tubes (inner diameter 10 cm). From reconstructed and filtered volumes, pores segmentation allows to study variations of structural porosity within the profile. Two kinds of porosity were identified: biological pores (tube-like) and physical pores (fracture-like). Structural porosity content varies strongly according to the horizons: from 5.48% in the L horizon to 6.48% in the S1/S2 horizon. The 3D connectivity of both of these pore types was also assessed. During sampling, soil shearing induced damages around the cores. Identification and quantification of the damaged zone was performed from the calculation of porosity profile from core surface to core heart. In average, the damaged zone reaches a depth of 1 cm. Porosity loss (compaction) or porosity increase (fracturing) was observed according to the studied profile. http://dx.doi.org/10.1051/epjconf/20100622023
collection DOAJ
language English
format Article
sources DOAJ
author Caner L.
Sardini P.
Robinet J.C.
Hubert F.
Gallier J.
spellingShingle Caner L.
Sardini P.
Robinet J.C.
Hubert F.
Gallier J.
Characterizing soil macroporosity by X-ray microfocus computed tomography and quantification of the coring damages.
EPJ Web of Conferences
author_facet Caner L.
Sardini P.
Robinet J.C.
Hubert F.
Gallier J.
author_sort Caner L.
title Characterizing soil macroporosity by X-ray microfocus computed tomography and quantification of the coring damages.
title_short Characterizing soil macroporosity by X-ray microfocus computed tomography and quantification of the coring damages.
title_full Characterizing soil macroporosity by X-ray microfocus computed tomography and quantification of the coring damages.
title_fullStr Characterizing soil macroporosity by X-ray microfocus computed tomography and quantification of the coring damages.
title_full_unstemmed Characterizing soil macroporosity by X-ray microfocus computed tomography and quantification of the coring damages.
title_sort characterizing soil macroporosity by x-ray microfocus computed tomography and quantification of the coring damages.
publisher EDP Sciences
series EPJ Web of Conferences
issn 2100-014X
publishDate 2010-06-01
description X-ray Computed Tomography (X-ray µCT) was employed to characterize vertical variations of structural porosity of a soil profile (pore dimension higher than 5.103 µm3). Three distinct horizons of a Cambisol have been studied for a total depth of 75 cm: L, S1/S2 and S2/SFe horizons. Samples have been cored in situ by driving in PVC tubes (inner diameter 10 cm). From reconstructed and filtered volumes, pores segmentation allows to study variations of structural porosity within the profile. Two kinds of porosity were identified: biological pores (tube-like) and physical pores (fracture-like). Structural porosity content varies strongly according to the horizons: from 5.48% in the L horizon to 6.48% in the S1/S2 horizon. The 3D connectivity of both of these pore types was also assessed. During sampling, soil shearing induced damages around the cores. Identification and quantification of the damaged zone was performed from the calculation of porosity profile from core surface to core heart. In average, the damaged zone reaches a depth of 1 cm. Porosity loss (compaction) or porosity increase (fracturing) was observed according to the studied profile.
url http://dx.doi.org/10.1051/epjconf/20100622023
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AT robinetjc characterizingsoilmacroporositybyxraymicrofocuscomputedtomographyandquantificationofthecoringdamages
AT hubertf characterizingsoilmacroporositybyxraymicrofocuscomputedtomographyandquantificationofthecoringdamages
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