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2013-14 Tour Information
Eastern North America:
• April 21-May 2, 2014
Shirley P. Dutton
Senior Research Scientist at the Bureau of Economic Geology, University of Texas at Austin
Funded by the AAPG Foundation Haas-Pratt Endowment
AAPG Foundation Haas-Pratt Lecturer
Shirley P. Dutton is a Senior Research Scientist at the Bureau of Economic Geology, The University of Texas at Austin, where she has spent her entire professional career. Her main area of research is in sandstone diagenesis, clastic sedimentology, and reservoir characterization. She received a B.A. from the University of Rochester and M.A. and Ph.D. degrees from The University of Texas at Austin, all in geology.
Dr. Dutton's current research involves diagenesis and reservoir quality of deep to ultradeep sandstones in the Gulf of Mexico. Dr. Dutton has broad experience in geologic characterization of low-permeability sandstone gas reservoirs. She was an AAPG Distinguished Lecturer in 1986-87 also.
Abstract: Diagenetic Controls on Reservoir Quality in Deep to Ultradeep Paleogene Wilcox Sandstones, Gulf of Mexico
Modern seismic methods have revealed large, deep structures in the northern Gulf of Mexico. Wilcox Group sandstones are deep (>4.5 km) to ultradeep (>6 km) exploration targets below the present-day shelf and deepwater Gulf. At these depths, reservoir quality is a critical risk factor. Petrographic study of onshore Wilcox sandstones, combined with burial-history modeling, provides insight into the main controls on regional variation of reservoir quality.
Wilcox sandstones were sourced by continental-scale drainage systems that terminated in deltas in Texas and Louisiana. Seismic data were used to identify three major sediment fairways that carried sandstone from the shelf into the deep basin in the northwestern Gulf. Sandstone composition and diagenetic history were determined by point counts of thin sections from onshore Wilcox samples from depths of 0.2â€“ 6.7 km, at temperatures of 25â€“230Â°C. The sandstones are mostly lithic arkoses and feldspathic litharenites; metamorphic and volcanic rock fragments are the most abundant lithic grains.
Primary, intergranular porosity was lost during diagenesis mainly by compaction (grain rearrangement and ductile-grain deformation) and quartz cementation. Pores in Wilcox sandstones changed from a mix of primary and secondary pores and micropores at lower temperatures to predominantly secondary pores and micropores at temperatures >150Â°C as primary pores were occluded. Primary porosity, which affects permeability the most, decreased from an estimated 40% at deposition to 5â€“8% by 125Â°C and 1â€“2% at temperatures >200Â°C. Pore-type evolution with temperature alters the porosityâ€“permeability transform.
Burial-history modeling reveals large differences in thermal history of Wilcox sandstones across the study area.Â Thermal maturity of Wilcox sandstones 6 km below the deepwater Gulf of Mexico is similar to that of onshore Louisiana Wilcox reservoirs at 3.4 km (both have Ro â‰ˆ 0.7%). Geothermal gradient in the deepwater Gulf is lower than onshore, and >3 km of allochthonous salt has been in place above the Wilcox for the past 30 m.y. Salt transmits heat effectively, thus reducing temperature and diagenesis in underlying Wilcox sandstones and preserving reservoir quality. During the past decade numerous oil discoveries have been made in Wilcox sandstones in the deepwater play. In contrast, Wilcox sandstones 8.2 km beneath the Louisiana shelf have higher thermal maturity (Ro > 2.7%). Allochthonous salt ~2.5 km thick was present for an estimated 8 m.y., but that time was apparently insufficient to lower thermal maturity. Deep, high-temperature Wilcox sandstones below the shelf have higher reservoir-quality risk.