Research output: Contribution to Journal/Magazine › Journal article › peer-review
Research output: Contribution to Journal/Magazine › Journal article › peer-review
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TY - JOUR
T1 - X-ray computed tomography of peat soils : measuring gas content and peat structure.
AU - Kettridge, Nicholas
AU - Binley, Andrew
PY - 2008/12/15
Y1 - 2008/12/15
N2 - The potential of using X-ray computed tomography (CT) to (i) analyse individual biogenic gas bubbles entrapped within peats and (ii) produce reliable descriptors of peat structure is examined. Existing approaches used to study biogenic gas bubbles measure the gas content of volumes of peat many orders of magnitude larger than most bubbles, and are, therefore, of little use in helping to understand bubble dynamics. In many peatland studies, the description of peat structures is derived from only a few relatively basic metrics; principally the porosity, the bulk density, and the von Post humification scale. CT is applied to identify and quantitatively analyse the size, location and shape of individual gas bubbles entrapped during the saturation of a 200 cm3 sample of S. fuscum. 3421 gas bubbles were identified, ranging in size from 0·1 mm3 to 99·9 mm3. These gas bubbles were non-randomly distributed, clustered predominantly in the vertical plane. When analysing the peat structure, Sphagnum peat and water are shown to be indistinguishable within CT scans. Peat samples were therefore prepared prior to scanning by flushing the peat with lead (II) nitrate solution to increase the linear attenuation of the Sphagnum. Sphagnum stems and branches were analysed, producing metrics of the peat structure; including stem and branch lengths, radii and orientation. In a 100 cm3 sample of S. magellanicum, the length of all Sphagnum stems totalled 1·82 m, with an average radius of 0·65 mm. The Sphagnum stems and branches were both preferentially orientated in the horizontal direction.
AB - The potential of using X-ray computed tomography (CT) to (i) analyse individual biogenic gas bubbles entrapped within peats and (ii) produce reliable descriptors of peat structure is examined. Existing approaches used to study biogenic gas bubbles measure the gas content of volumes of peat many orders of magnitude larger than most bubbles, and are, therefore, of little use in helping to understand bubble dynamics. In many peatland studies, the description of peat structures is derived from only a few relatively basic metrics; principally the porosity, the bulk density, and the von Post humification scale. CT is applied to identify and quantitatively analyse the size, location and shape of individual gas bubbles entrapped during the saturation of a 200 cm3 sample of S. fuscum. 3421 gas bubbles were identified, ranging in size from 0·1 mm3 to 99·9 mm3. These gas bubbles were non-randomly distributed, clustered predominantly in the vertical plane. When analysing the peat structure, Sphagnum peat and water are shown to be indistinguishable within CT scans. Peat samples were therefore prepared prior to scanning by flushing the peat with lead (II) nitrate solution to increase the linear attenuation of the Sphagnum. Sphagnum stems and branches were analysed, producing metrics of the peat structure; including stem and branch lengths, radii and orientation. In a 100 cm3 sample of S. magellanicum, the length of all Sphagnum stems totalled 1·82 m, with an average radius of 0·65 mm. The Sphagnum stems and branches were both preferentially orientated in the horizontal direction.
KW - X-ray computed tomography • peatland • gas bubbles • peat structure
U2 - 10.1002/hyp.7097
DO - 10.1002/hyp.7097
M3 - Journal article
VL - 22
SP - 4827
EP - 4837
JO - Hydrological Processes
JF - Hydrological Processes
SN - 0885-6087
IS - 25
ER -