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Wiseall, A. C., Cuss, R. J., Graham, C. C., Harrington, J. F. (2015) The visualization of flow paths in experimental studies of clay-rich materials. Mineralogical Magazine, 79 (6) 1335-1342 doi:10.1180/minmag.2015.079.06.09

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Reference TypeJournal (article/letter/editorial)
TitleThe visualization of flow paths in experimental studies of clay-rich materials
JournalMineralogical Magazine
AuthorsWiseall, A. C.Author
Cuss, R. J.Author
Graham, C. C.Author
Harrington, J. F.Author
Year2015 (November)Volume79
Issue6
PublisherMineralogical Society
DOIdoi:10.1180/minmag.2015.079.06.09Search in ResearchGate
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Mindat Ref. ID244702Long-form Identifiermindat:1:5:244702:9
GUID0
Full ReferenceWiseall, A. C., Cuss, R. J., Graham, C. C., Harrington, J. F. (2015) The visualization of flow paths in experimental studies of clay-rich materials. Mineralogical Magazine, 79 (6) 1335-1342 doi:10.1180/minmag.2015.079.06.09
Plain TextWiseall, A. C., Cuss, R. J., Graham, C. C., Harrington, J. F. (2015) The visualization of flow paths in experimental studies of clay-rich materials. Mineralogical Magazine, 79 (6) 1335-1342 doi:10.1180/minmag.2015.079.06.09
Abstract/NotesAbstractOne of the most challenging aspects of understanding the flow of gas and water during testing in clay-rich low-permeability materials is the difficulty in visualizing localized flow. Whilst understanding has been increased using X-ray Computed-tomography (CT) scanning, synchrotron X-ray imaging and Nuclear Magnetic Resonance (NMR) imaging, real-time testing is problematic under realistic in situ conditions confining pressures, which require steel pressure vessels. These methods tend not to have the nano-metre scale resolution necessary for clay mineral visualization, and are generally not compatible with the long duration necessary to investigate flow in such materials. Therefore other methods are necessary to visualize flow paths during post-mortem analysis of test samples. Several methodologies have been established at the British Geological Survey (BGS), in order to visualize flow paths both directly and indirectly. These include: (1) the injection of fluorescein-stained water or deuterium oxide; (2) the introduction of nanoparticles that are transported by carrier gas; (3) the use of radiologically tagged gas; and (4) the development of apparatus for the direct visualization of clay. These methodologies have greatly increased our understanding of the transport of water and gas through intact and fractured clay-rich materials. The body of evidence for gas transport through the formation of dilatant pathways is now considerable. This study presents observations using a new apparatus to directly visualize the flow of gas in a kaolinite paste. The results presented provide an insight into the flow of gas in clay-rich rocks. The flow of gas through dilatant pathways has been shown in a number of argillaceous materials (Angeli et al., 2009; Autio et al., 2006; Cuss et al., 2014; Harrington et al., 2012). These pathways are pressure induced and an increase in gas pressure leads to the dilation of pathways. Once the gas breakthrough occurs, pressure decreases and pathways begin to close. This new approach is providing a unique insight into the complex processes involved during the onset, development and closure of these dilatant gas pathways.

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Cuss, R. J., Harrington, J. F., Graham, C. C., Sathar, S., Milodowski, A. E. (2012) Observations of heterogeneous pore pressure distributions in clay-rich materials. Mineralogical Magazine, 76 (8) 3115-3129 doi:10.1180/minmag.2012.076.8.26
Harrington, J. F., Milodowski, A. E., Graham, C. C., Rushton, J. C., Cuss, R. J. (2012) Evidence for gas-induced pathways in clay using a nanoparticle injection technique. Mineralogical Magazine, 76 (8) 3327-3336 doi:10.1180/minmag.2012.076.8.45
Graham, C. C., Harrington, J. F., Cuss, R. J., Sellin, P. (2012) Gas migration experiments in bentonite: implications for numerical modelling. Mineralogical Magazine, 76 (8) 3279-3292 doi:10.1180/minmag.2012.076.8.41
Sathar, S., Reeves, H. J., Cuss, R. J., Harrington, J. F. (2012) The role of stress history on the flow of fluids through fractures. Mineralogical Magazine, 76 (8) 3165-3177 doi:10.1180/minmag.2012.076.8.30
Harrington, J. F., de la Vaissière, R., Noy, D. J., Cuss, R. J., Talandier, J. (2012) Gas flow in Callovo-Oxfordian claystone (COx): results from laboratory and field-scale measurements. Mineralogical Magazine, 76 (8) 3303-3318 doi:10.1180/minmag.2012.076.8.43
Zihms, S. G., Harrington, J. F. (2015) Thermal cycling: impact on bentonite permeability. Mineralogical Magazine, 79 (6) 1543-1550 doi:10.1180/minmag.2015.079.6.29
Bennett, D. P., Cuss, R. J., Vardon, P. J., Harrington, J. F., Philp, R. N., Thomas, H. R. (2012) Data analysis toolkit for long-term, large-scale experiments. Mineralogical Magazine, 76 (8) 3355-3364 doi:10.1180/minmag.2012.076.8.48
Harrington, J. F., Graham, C. C., Cuss, R. J., Norris, S. (2019) Gas Network Development in Compact Bentonite: Key Controls on the Stability of Flow Pathways. Geofluids, 2019. 1-19 doi:10.1155/2019/3815095
Graham, J., Morris, R. C. (1973) Tungsten- and antimony-substituted rutile. Mineralogical Magazine, 39 (304) 470-473 doi:10.1180/minmag.1973.039.304.11
Curtis, C. D., Hughes, C. R., Ireland, B. J., Warren, E. D., Whiteman, J. A., Whittle, C. K. (1987) Analytical transmission electron microscopy in the study of diagenetic clay minerals. Mineralogical Magazine, 51 (359) 123-124 doi:10.1180/minmag.1987.051.359.11
Grey, I. E., Keck, E., Mumme, W. G., MacRae, C. M., Price, J. R., Glenn, A. M., Davidson, C. J. (2015) Crystallographic ordering of aluminium in laueite at Hagendorf-Süd. Mineralogical Magazine, 79 (2) 309-319 doi:10.1180/minmag.2015.079.2.09
 
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