T23C-4691:
Shallow properties of faults in carbonate rocks – The Jandaíra Formation, Potiguar Basin, Brazil
Tuesday, 16 December 2014
Francisco H Bezerra1, Giovanni Bertotti2, Juliana Rabelo1, Aline Teophilo Silva3, Mikaelle Araujo Carneiro1, Caroline Lessio Cazarin3, Carlos Cesar Silva1, Marcela Marques Vieira1, Kevin Bisdom4 and Anderson Moraes3, (1)UFRN Federal University of Rio Grande do Norte, Natal, Brazil, (2)VU University, Amsterdam, Netherlands, (3)PETROBRAS, CENPES, Rio De Janeiro, Brazil, (4)Delft University of Technology, Geological Sciences, Delft, Netherlands
Abstract:
We studied the development of shallow faults in the Jandaíra Formation, a Turonian-Campanian carbonate platform in the Potiguar Basin, northeastern Brazil. Our main goal was to characterize fault geometry and properties such as porosity and permeability, and associate these results with fluid flow in shallow conditions. We used an integrated multidisciplinary approach, which combined Quickbird satellite and an unmanned aerial vehicle (UAV, drone) imagery, structural and sedimentary-facies mapping, and petrographic and petrophysical analyses. The Jandaíra Formation presents a variety of carbonate facies, which include mudstones to bioclastic, peloidal, intraclastic, and oolitic grainstones. We modeled our remote sensing and structural data using a finite element analysis system for 2D deformation modeling. We applied the magnitudes and directions of the present-day stress field to simulate depths as deep as 500 m. These stress data were derived from borehole breakout data and drilling-induced tensile fractures observed in resistivity image logs. Our results indicate the occurrence of dilation processes along three sets of joints that were reactivated as faults in the upper crust: N-S, NE-, and E-W-striking faults. These faults provided preferential leaching pathways to fresh water percolation, contributing to localized dissolution and increased secondary porosity and permeability. The results also indicate that the tectonic stresses are concentrated in preferred structural zones such as fault intersection and termination, which are sites of increased fracturing and dissolution. Dissolution by fluids increased permeability in carbonate rocks from primary values of 0.0–0.94 mD to as much as 1370.11 mD. This process is mostly Cenozoic.