Duvernay Formation

Duvernay Formation
Stratigraphic range: Frasnian
TypeGeological formation
Unit ofWoodbend Group
UnderliesIreton Formation, Grosmont Formation
OverliesCooking Lake Formation, Majeau Lake Formation
Thicknessup to 250 metres (820 ft)[1]
Lithology
PrimaryShale
OtherCalcarenite, mudstone
Location
Coordinates53°18′12″N 112°23′00″W / 53.303272°N 112.383197°W / 53.303272; -112.383197 (Duvernay Formation)
RegionWCSB
Country Canada
Type section
Named forDuvernay, Alberta
Named byAndrichuk and Wonfor
Year defined1954
Duvernay Formation is located in Canada
Duvernay Formation
Duvernay Formation (Canada)

The Duvernay Formation is a stratigraphical unit of Frasnian age in the Western Canadian Sedimentary Basin.

It was first described in well Anglo Canadian Beaverhill Lake No. 2 in LSD 11-11-50-17W4M by Imperial Oil staff in 1950.[2] The formation was named by Andrichuk and Wonfor in 1954[3] for the type section in Duvernay, Alberta.

According to Canada's Alberta Energy Regulator, the Duvernay Formation "holds an estimated 443 trillion cubic feet of gas and 61.7 billion barrels of oil (Penny China Institute 2012-12)."[4] Calgary-based, Athabasca Oil Corporation (formerly Athabasca Oil Sands Corporation), holds 640,000 acres, the largest publicly disclosed Duvernay rights.[4]

Lithology

The Duvernay Formation is composed of laminated bituminous shale, calcareous shale and dense argillaceous limestone. Pyrite disseminations are common. Calcarenite and coral rich mudstone are also present. [1]

Hydrocarbon production

The Duvernay Formation represents the source rock for prolific reservoirs such as the Leduc reefs. Shale gas and condensate is produced from the Duvernay Formation in central Alberta using horizontal drilling and multi-stage hydraulic fracturing.[5] $2 billion was paid for leases during 2010 and 2011. Prices for land remained high as of June, 2012 despite costs of drilling being expensive. Parts of the deposit show total organic carbon of 11%.[6][7]

Hydraulic fracturing in Canada

Massive hydraulic fracturing has been widely used in Alberta since the late 1970s.[8]: 1044  The method is currently used in development of the Cardium, Duvernay, Montney and Viking formations in Alberta, Bakken formation in Saskatchewan, Montney and Horn River formations in British Columbia.

Distribution

The Duvernay Formation is present in the sub-surface in central Alberta.[1] It reaches a maximum thickness of 250 metres (820 ft) east of Lesser Slave Lake.

Relationship to other units

The Duvernay Formation is a unit of the Woodbend Group. It is conformably overlain by the Ireton Formation and Grosmont Formation and it conformably overlays the Cooking Lake Formation.[1]

It is equivalent to the Leduc Formation reefs. it is equivalent to the Perdrix Formation in the Rocky Mountains, and is the stratigraphical equivalent of the Muskwa Formation in the Fort Nelson area of North-Eastern British Columbia.

See also

References

  1. ^ a b c d Lexicon of Canadian Geologic Units. "Duvernay Formation". Retrieved 2012-01-26.[permanent dead link]
  2. ^ Geological Staff, Imperial Oil Ltd. Western Division, 1950. Devonian nomenclature in Edmonton area. Bulletin of American Association of Petroleum Geologists, v. 34, p. 1807-1825.
  3. ^ Andrichuk, J.M. and Wonfor, J.S., 1954. Late Devonian geologic history in Stettler area, Alberta, Canada Bulletin of American Association of Petroleum Geologists, v. 38, p. 2500-2536.
  4. ^ a b Rebecca Penty (December 17, 2012). "Encanas PetroChina Partnership May Be First of Many". Edmonton, AB: China Institute, University of Alberta. Archived from the original on December 3, 2013. Retrieved February 1, 2013.
  5. ^ "The Duvernay Shale". Retrieved 2012-03-04.
  6. ^ Keith Schaefer (June 13, 2012). "The Duvernay shale is a colossal oil and gas play". Mining.Com. Retrieved June 13, 2013.
  7. ^ "Technically Recoverable Shale Oil and Shale Gas Resources: An Assessment of 137 Shale Formations in 41 Countries Outside the United States" (PDF). U.S. Energy Information Administration (EIA). June 2013. Retrieved June 11, 2013.
  8. ^ Cant, Douglas J.; Ethier, Valerie G. (August 1984), "Lithology-dependent diagenetic control of reservoir properties of conglomerates, Falher member, Elmworth Field, Alberta", Bulletin of the American Association of Petroleum Geologists, 68 (8)