Fracture controlled permeability of ultramafic basement aquifers. Inferences from the Koniambo massif, New Caledonia

Fracture controlled permeability of ultramafic basement aquifers. Inferences from the Koniambo massif, New Caledonia

We study the relationship between fracture distribution and permeability in weathered peridotites exposed to tropical climate using the data from the Koniambo massif (New Caledonia, South Pacific). The vertical distribution of hydraulic conductivity is obtained from packer tests performed on four 20...

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Bibliographic Details
Published in:Engineering geology Vol. 256; pp. 67 - 83
Main Authors: Jeanpert, J., Iseppi, M., Adler, P.M., Genthon, P., Sevin, B., Thovert, J.-F., Dewandel, B., Join, J.-L.
Format: Journal Article
Language:English
Published: Elsevier B.V 05-06-2019
Elsevier
Subjects:
Applied geology
Boreholes data
Earth Sciences
Hydraulic conductivity
Multi-scale fracture network
New Caledonia
Sciences of the Universe
Ultramafic aquifer
Weathered fracture
Ultramafic aquifer
Weathered fracture
Multi-scale fracture network
Hydraulic conductivity
New Caledonia
Boreholes data
TECTONICS
SOUTHWEST PACIFIC
HARD-ROCK AQUIFERS
CONCEPTUAL-MODEL
NETWORKS
OPHIOLITE
GRANDE TERRE
HYDRAULIC CONDUCTIVITY
CONVERGENCE
PERIDOTITE NAPPE
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Summary:We study the relationship between fracture distribution and permeability in weathered peridotites exposed to tropical climate using the data from the Koniambo massif (New Caledonia, South Pacific). The vertical distribution of hydraulic conductivity is obtained from packer tests performed on four 200-m-deep boreholes. A positive correlation is observed between the cumulated width of weathered fractures and the hydraulic conductivity in a given depth-interval. Therefore, a two-scale model of weathered fractures is developed with small fractures (5 m radius) deduced from outcrop data and large fractures (50 m radius) from a remote sensing analysis. Hydraulic conductivity is 10−5 m/s in the fractures and 10−8 m/s in the matrix. Permeability fields are computed for the synthetic fractures network models, either from flow along the three axes of a periodic cube or from injection through a slit. Then, results are compared to packer tests and show that when both sets of large and small fractures are included, the proposed model reproduces reasonably in situ measured data. Analytical formulae are proposed for computing an approximate permeability from field data. The decrease of hydraulic conductivity with depth is also discussed. We show that the proposed model for peridotites aquifers is similar to the one currently admitted for granitic rock aquifers. It relies on weathering of a pre-existing serpentine-bearing fractures network which controls permeability in the weathering profile itself, but also deeper in the fresh and non-weathered rock. The proposed conceptual model allows deriving quantitative estimate of hydraulic conductivity from field data which are of primary interest for managing the groundwater resource of peridotite aquifers, particularly where mining operations impact groundwater flow. •Weathered fractures are proposed to control the permeability of peridotite aquifers.•A two-scale fracture network is built from remote sensing, outcrop and core data.•Numerical models are built to reproduce in situ packer test measurements.•Numerical flow modelling in the fracture network reproduces measured permeability.•Analytical formulae for fracture networks fairly fit permeability data.
ISSN:0013-7952
1872-6917
DOI:10.1016/j.enggeo.2019.05.006