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The AAPG/Datapages Combined Publications Database
AAPG Bulletin
Abstract
AAPG Bulletin, V.
Simulation of potassium feldspar dissolution and illitization in the Statfjord Formation, North Sea
Geoffrey Thyne,1 Bernard P. Boudreau,2 Mogens Ramm,3 Ruth Elin
Midtbo4
1Colorado School of Mines, Golden, Colorado, 80401; email: [email protected]
2School of Ocean and Earth Sciences, University of Southampton, European Way, Southampton, SO14 3ZH, United Kingdom
3Norsk Hydro E&P, Postboks 200, 1321 Stabekk, Vækero, Oslo, Norway
4Norsk Hydro Research Centre, Sandsliveien 90, N-5020, Bergen, Norway
AUTHORS
Geoffrey Thyne earned his Ph.D. in geology from the University of Wyoming in 1990. Since 1996 he has held the position of research associate professor in the Department of Geology and Geological Engineering at Colorado School of Mines and regularly consults in the petroleum industry. He was an assistant professor at California State University-Bakersfield (1991-1996) and a research geochemist for Arco Oil and Gas in Plano, Texas (1979-1986). His research interests continue to focus on the mysteries of siliciclastic diagenesis. His current research and consulting projects involve the quantitative prediction of the effects of diagenesis on the reservoir quality.
As of August 2000, Bernard Boudreau occupies the position of Professor and Chair in Benthic Processes in the School of Ocean and Earth Science of Southampton University (United Kingdom). Boudreau received his Ph.D. from Yale University in 1985 and held various academic posts at the University of British Columbia and Dalhousie University (Canada) before moving to the United Kingdom. He is the author of more than 45 scientific papers and two textbooks. His interests center on modeling diagenesis, sediment-water exchange, and benthic processes in general.
Mogens Ramm earned his Dr. Scient. in diagenesis and reservoir quality prediction at the University of Oslo in 1991. He is currently with the Norsk Hydro E&P division. Since 1999 he has been working as project leader in the North Sea exploration group. After finishing his Cand. Scient. degree in 1986, he spent five years at the University of Oslo, on VISTA (the Norwegian Academy of Science and Letters and Statoil) and University funding. In 1991 he joined the Norsk Hydro E&P Research Center before he left for the Exploration Sector in 1994 and the Technology and Competence Sector in 1997. Coordination and advising of research and development works addressing prospect generation and evaluation in deeply buried structures has been one of his main responsibilities.
Ruth Elin A. Midtbo finished her M.S. degree in engineering in December 1992 and has since worked at Norsk Hydro E&P Research Center. She is employed as a petrologist in the Department of Sedimentology and Stratigraphy. Her main interest is siliciclastic diagenesis. Her work has been mainly focused on the effect of diagenesis on reservoir quality in sandstones and how this relates to sedimentological facies.
ACKNOWLEDGMENTS
We would like to gratefully acknowledge the financial support of Norsk Hydro. Discussions with Knut Bjorlykke and Wendy Harrison were instrumental in the early conceptual development. The editorial handing by Julie Kupecz and reviews by Kitty Lou Milliken and Ian Hutcheon were much appreciated and significantly improved the final product.
ABSTRACT
Prior work has suggested that potassium mobility is an important control on the formation of late-stage illite in deep reservoirs of the North Sea. We developed a one-dimensional finite-difference reactive transport model to simulate the concurrent dissolution of K-feldspar and illitization of kaolinite in Statfjord Formation reservoirs. The kinetics of K-feldspar dissolution is set to be faster than diffusion, consistent with the observed behavior and the proposition that the reaction was transport-limited. K-feldspar dissolution produced dissolved potassium and silica that diffused and then precipitated to form illite and quartz. Areas that had higher initial reactant (K-feldspar) produced higher solute concentrations and formed chemical gradients having areas that had lower initial feldspar content. In typical North Sea cases this means mass transfer would be from sandstone to shale. The diffusive transport moved significant amounts of potassium and silica over distances of several meters and created observable diagenetic alteration.
Simulations of an oil-filled reservoir showed that oil emplacement did not stop illitization but did limit potassium mobility and maximized illite formation within the sandstone. Preservation of preillitization permeability was favored in water-filled reservoirs that had slower illite formation where diffusion could export potassium from the sandstone before precipitation. Similar patterns of transport and precipitation were predicted for silica from K-feldspar dissolution. The results of the model showed good agreement with field data from other North Sea reservoirs.
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