uIntroduction

uFigure captions

uData set

uResults

uApplication

uReferences

uIntroduction

uFigure captions

uData set

uResults

uApplication

uReferences

uIntroduction

uFigure captions

uData set

uResults

uApplication

uReferences

uIntroduction

uFigure captions

uData set

uResults

uApplication

uReferences

uIntroduction

uFigure captions

uData set

uResults

uApplication

uReferences

Data Set 

The following data was collected:

·         A vertical pilot hole (the 816) was drilled and continuously cored from the overlying shale, through the caprock, and into the underlying halite. A full suite of logs was collected in the 816, including an electrical image log and a crossed-dipole sonic log.

·         A crosswell tomogram was shot between the 816 and an existing well (the 795) that had a suite of conventional logs.

·         A horizontal well was drilled through the plane of the tomogram, and was oriented to optimally sample the fracture network based on observations in the pilot hole.

·         The horizontal well was logged and an image log was collected.

Results 

We find that the caprock fracture system developed during caprock growth and that development of the fracture system is linked to salt-dome movement. The caprock was fractured both by faulting and extensional fracturing resulting from dome emplacement and by mineral volume changes occurring during conversion of anhydrite to calcite. Isotopic data from the limestones (d¹⁸O: -4 to -8 PDB, and d¹³C: -11 to -31 PDB) suggest that fluids evolved from deep bacterial to mixed meteoric during dome ascent. Paleostress analysis based on fault-slip kinematics and extensional fracturing shows that caprock strain was due to dome inflation and that this expansion bears an overprint of the neotectonic (present-day) stress field. We interpret that previously unrecognized pockets of fractured limestone exist deep within the Sour Lake anhydrite layer and that these pockets represent a significant positive modification of traditional salt dome caprock reservoir volume. Some of these pockets are both sampled by wells and imaged on the crosswell tomogram. The fractured limestone pockets within the anhydrite resulted from bacterially-mediated diagenetic reactions that occurred when petroleum and brine flowed through faults resulting from dome expansion.  

This study targeted an undrilled area that was thought to represent an isolated fault block. The caprock was found to have a very well developed fracture system and to have excellent fracture porosity and permeability. Although the core from the pilot hole was oil soaked and although there were numerous oil shows during drilling of the horizontal well, the horizontal well tested ~30,000 barrels of water/day and little oil. We speculate that the fault block is not isolated and that the oil was produced and/or flushed-out by disposal water that was injected elsewhere in the dome.

Application 

The conditions that produced the fracture porosity and permeability at Sour Lake are the same processes that operate on all salt domes that develop caprock. Consequently, Sour Lake could be a typical example of a caprock fracture system and results of this study might be applied more broadly to caprocks in mobile salt basins. This study has direct application to oil and gas operations and construction of storage facilities in salt domes. The discovery of porous volumes within the anhydrite layer is especially significant because until now only the limestone layer was thought to have porosity and permeability.

References 

Halbouty, M.T., and G.C. Hardin, Jr., 1955, Factors affecting quantity of oil accumulation around some Texas Gulf Coast piercement-type salt domes: AAPG Bulletin, v. 39, p. 697-711.

Looff, K., M., 2001, Recent salt related uplift and subsidence at Sour Lake salt dome, Hardin County, Texas: GCAGS Transactions, v. 51, p. 187-194.

Return to top.