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Play Concepts for Reopening the Bristol Bay Basin: Tertiary and Mesozoic
Petroleum Systems of the 
Alaska
Peninsula*
By
Paul L. Decker1, Rocky R. Reifenstuhl2, Emily S. Finzel2, and Kenneth P. Helmold1
Search and Discovery Article #10106 (2006)
Posted July 20, 2006
*Oral presentation at AAPG Annual Convention, Houston, Texas, April 9-12, 2006
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1Alaska
Division of Oil & Gas, Anchorage, AK ([email protected])
2Alaska
Division of Geological & Geophysical Surveys, Fairbanks, AK
Abstract
Alaska's frontier
Bristol Bay basin reopened for state leasing in 2005 after a two- decade hiatus.
The new annual areawide sale, encompassing 5.8 million acres, is dramatically
under-explored with only 11 wells drilled, all between 1959 and 1985. Interest
focuses on the northwestern Alaska Peninsula, which parallels the thick
southeastern side of the asymmetric back-arc basin. Cenozoic basin fill ranges
from > 15,000 feet thick below state waters to zero in nearby uplifts with
exposed oil-window Mesozoic strata. A complex subsidence and uplift history
makes this margin prospective for structural and stratigraphic plays in both
Mesozoic and Tertiary hydrocarbon systems.
Mesozoic sources
generate oil and gas seeps on the eastern Alaska Peninsula, and probably also
source a vigorous seep of thermogenic methane on a major surface anticline in
the sale area. Mesozoic sandstones are degraded by zeolites, but may constitute
gas reservoirs, particularly where highly fractured. Lower Cretaceous marine
mudstones may seal Jurassic gas reservoirs.
Depending on maturity, Upper Cretaceous to Tertiary coals and carbonaceous mudstones may be excellent sources for either thermogenic or biogenic gas. RockEval and kerogen analyses suggest that Paleogene coals and shales may generate some light oil or condensate, and isotopic and gas wetness data support a liquids-associated thermogenic origin for some Tertiary gas shows. Several Tertiary sandstones would be fair to excellent oil or gas reservoirs, particularly the Miocene Bear Lake Formation and equivalents. Mudstones interbedded with reservoir sands are likely to provide intraformational seals, as in the partially analogous Tertiary system of Cook Inlet.
Selected Figures
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State of |
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Stratigraphic column, |
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Regional seismic interpretation of lines AA’ and BB’ , with North Aleutian COST #1 on AA’. |
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Composite regional seismic |
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References
Finzel, Emily S., Kenneth D. Ridgway, Paul Decker, and Rocky R.
Reifenstuhl, 2005, Reservoir characterization of the Bear Lake and Milky River
formations, Bristol Bay basin, Alaska Peninsula (abs.): AAPG Bulletin.
Helmold, K.P., and D.W. Brizzolara,
2005, Reservoir Quality of Tertiary Sandstones from Bristol Bay Basin, Alaska
Peninsula: Preliminary Report: State of Alaska Department of Natural Resources.
Hite, David, 2005, Hydrocarbon
Potential of the Alaska Peninsula and Bristol Bay basin, Southern Alaska —
Emphasis on Bristol Bay Native Corporation Lands: BBNC.
Ridgway, Kenneth D, Rocky R.
Reifenstuhl, and Emily S. Finzel, 2005, Stratigraphic architecture of the Bear
Lake Formation, Bristol Bay basin, Alaska
Peninsula: AAPG Bulletin, v. 89.
Schoell, M., 1983, v. 67, Genetic Characterization of Natural Gases: AAPG Bulletin, v. 67, p. 2225-2238.
Schreurs, G., and B. Colletta, 2002, Analogue modeling of continental transpression, in W.P. Schellart and C. Passchier, eds., Analogue modeling of large-scale tectonic processes: Journal of the Virtual Explorer, v. 6, p. 67-78.