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Detailed Reference Information |
Gouze, P., Noiriel, C., Bruderer, C., Loggia, D. and Leprovost, R. (2003). X-ray tomography characterization of fracture surfaces during dissolution. Geophysical Research Letters 30: doi: 10.1029/2002GL016755. issn: 0094-8276. |
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The changes of fracture surfaces geometry and extend are studied using X-ray tomography during aperture increase due to CO2-rich fluid percolation. Dissolution experiments were conducted on two micritic rock samples; one pure calcite end-member and one with typical composition for marine carbonates (85% calcite). High-resolution digital images of the fracture geometry allow quantifying the surface properties changes over four spatial scales with a resolution of 4.91 ¿m. Fracture surfaces are self-affine with an initial dimension of 2.5. Dissolution of the pure-calcite sample is clearly a process of homogeneous chemical erosion of the surface elevation: fractal dimension and specific surface remains constant (1.5 times the planar surface). Conversely, for the 85% calcite sample, initial topographic surfaces of the fracture walls evolve rapidly toward non-topographic interfaces displaying overhangs due the preferential dissolution of the carbonate grains. In this case, the conventional definition of the effective aperture must be revisited. Such structures can only be assessed from 3D observations. As dissolution progresses, the specific surface increases strongly, more than 5 times the planar surface, and probably faster than the reactive surface. |
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Abstract |
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Keywords
Physical Properties of Rocks, Fracture and flow, Physical Properties of Rocks, Transport properties, Physical Properties of Rocks, Permeability and porosity, Physical Properties of Rocks, Microstructure, Physical Properties of Rocks, Instruments and techniques |
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Publisher
American Geophysical Union 2000 Florida Avenue N.W. Washington, D.C. 20009-1277 USA 1-202-462-6900 1-202-328-0566 service@agu.org |
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