Fractures: Finite-size scaling and multifractals |
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Authors: | L. J. Pyrak-Nolte L. R. Myer D. D. Nolte |
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Affiliation: | (1) Department of Civil Engineering and Geological Sciences, University of Notre Dame, 46556 Notre Dame, IN;(2) Earth Science Division, Lawrence Berkeley Laboratory, 94720 Berkeley, CA, USA;(3) Department of Physics, Purdue University, 47907-1396 West Lafayette, IN, USA |
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Abstract: | The distributions of contact area and void space in single fractures in granite rock have been determined experimentally by making metal casts of the void spaces between the fracture surfaces under normal loads. The resulting metal casts on 52 cm diameter core samples show a complex geometry for the flow paths through the fracture. This geometry is analyzed using finite-size scaling. The spanning probabilities and percolation probabilities of the metal casts are calculted as functions of observation scale. Under the highest stresses of 33 MPa and 85 MPa there is a significant size-dependence of the geometric flow properties for observation scales smaller than 2 mm. Based on this data, the macroscopic percolation properties of the extended fracture can be well represented by relatively small core samples, even under normal stresses larger than 33 MPa. The metal casts also have rich multifractal structure that changes with changing stress. |
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Keywords: | Fractures fractals multifractals scaling percolation geohydrology rock mechanics permeability |
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