Home Mission 2007 Team Members Research Sources Progress Journal	Research - Geologic History Moore, T.E., Wallace, W.K., Bird, K. J., Karl, S.M., Mull, C.G., and Dillon, J.T., 1994, Geology of northern Alaska, in Plafkler, G., and Berg, H.C., eds., The Geology of Alaska: Boulder, Colorado, Geological Society of America, The Geology of North America, v. G-1. BIRD, K.J. (1999). Geographic and Geologic Setting. In The Oil and Gas Resource Potential of the 1002 Area, Arctic National Wildlife Refuge, Alaska. By ANWR Assessment Team, U.S. Geological Survey Open-File Report 98-34. Geographic Placement The 1002 area of the Arctic National Wildlife Refuge is a 1.5-million-acre area in northeastern Alaska. It is bounded on the east by the Canning and Staines Rivers, on the north by the Beaufort Sea, on the east by the Aichilik River and the Canadian border, and to the south by Brooks Range. Most of the 1002 area lies within the Arctic Coastal Plain physiographic province, a marshy area that slopes gradually towards the Arctic Ocean on the north. A small part along the southern margin that constitutes less than 5% of the total area lies within the Arctic Foothills physiographic province, a series of hills and ridges that descend from more than 500 m in the Brooks Range to 300 m in elevation to the northern foreland. Beaches, low steep cliffs, barrier islands, shallow lagoons, and river deltas form the coast of the 1002 area, with hills rising to more than 300 m in the south. Many rivers and stream flow between these hills towards the Arctic Ocean. Origin The North Slope and its continental shelves, Brooks Range and the northeaster part of Siberia are considered to form the Arctic Alaska microplate, a small lithospheric plate with boundaries that are not clearly known. One hypothesis for the plate tectonic history of northern Alaska suggests that the region was originally next to the Canadian Arctic Islands. Creation of oceanic crust in the Canada basin during the Jurassic and Early Cretaceous caused the microplate to rotate 60 degrees counter clockwise, placing it in its current position. Surface Geology Nearly all of the surface of the 1002 area is covered by a thin layer, less than 30 m thick, of unconsolidated, frozen silt- to gravel-sized sediments of nonmarine origin. They originated from the erosion of the Brooks Range during the late Cenozoic. The surface exposures of rock formations inside the 1002 area are mostly restricted to deposits of the Sagavanirktok, Jago River, and Canning Formations of Tertiary age. There are some smaller outcrops of Hue Shale, pebble shale unit, and Kingak Shale from the Cretaceous and the Jurassic. To the east of the Sadlerochit Mountains, in the southern border of the 1002 area, some of the oldest exposures, of limestones from the Mississippian Lisburne Group, are found. Subsurface Structure Tectonics: During the rifting that separated northern Alaska from the Canadian Arctic Island, the Barrow arch, a structural high, was formed. The northern side of the Barrow arch formed the continental margin, while the southern flank received the thrust of the formation of the Brooks Range orogen. The part of the 1002 area located to the south and east of the Marsh Creek anticline and north of 69-degrees is the Brooks Range orogen. The Brooks Range is more than 1000 km long and up to 300 km wide, and the distribution and character of its major structures is not symmetrical. Deformations in this region occurred during the Cenozoic era, forming both east-northeastward and eastward structures. Parts of Jurassic to Cretaceous shales, Mississippian shales, and of a horizon in the pre-Mississippian basement rocks were separated from their source due to extreme folding and compression. The structure of the Brooks Range is formed by a series of broad anticlines with a core of pre-Mississippian rocks and younger rocks deformed on the borders. To the north of the Brooks Range, the structure, called thin-skinned deformation, is composed of numerous folds and faults developed in rocks of Cenozoic and Mesozoic age. Several broad domes are present in pre-Mississippian rocks in that area. Stratigraphy The stratigraphic record of the North Slope is divided into three sequences: Franklinian, Ellesmerian and Brookian. The Franklinian sequence comprises a thick succession of mainly sedimentary rocks with a minor amount of igneous rocks of Cambrian to Devonian age that lie beneath the pre-Mississippian unconformity, where a gap in the geologic record exists. Two separate layers of rock are present in northern Alaska. The shallow marine carbonates are composed of rocks of Proterozoic age and rocks of Lower Devonian age, separated by unconformities where Silurian strata are missing. They are composed of quartzite (metamorphic rock consisting of quartz grains, formed by recrystalization of sandstone), argillite compact rock derived from mudstone or shale, product of weak metamorphism), and basalt (dark-colored igneous rock), with intrusions of sandstone (the consolidate equivalent of sand, with 85-90% quartz), and shale (fine-grained sedimentary rock, formed by clay, silt or mud). The deeper marine layers include quartzite, conglomerate, phyllite (metamorphic rock, finer than schist), argilite, limestone (sedimentary rock formed by calcium carbonates), and granite (light-colored, coarse-grained igneous rock). The compression, uplift and erosion of this sequence during the Ellesmerian orogeny formed the pre-Mississippian unconformity. The Ellesmerian sequence is hundreds of meters thick, and is composed of layers of marine and nonmarine sedimentary rocks of Middle Devonian to Triassic age, that rests on top of the pre-Mississippian unconformity. The lower unit of this sequence is the Endicott Group, which, in the 1002 area, consists of Mississippian coal-bearing sandstone, conglomerate, and shale of the Kekiktuk Conglomerate and Kayak Shale, of Devonian and Mississippian age. The Kekiktuk Conglomerate is a proven oil-bearing reservoir. Large amounts of limestone and dolomine of the Lisburne Group were deposited in the North Slope up to a thickness of 500 to 1000 meters during the Mississippian and Pennsylvanian. It is separated from the overlying Sadlerochit Group by an unconformity formed during the Middle Pennsylvanian to Early Permian in when sea level fell. Water resources Snow: The North Slope is covered in snow from October to May of every year, and while snow might fall during any month, the precipitation during the summer is mainly rain. In spring, melting snow is the main source of water for lakes and streams in that region, and water stored in snowdrifts is released slowly and provides water for them during the summer. In the 1002 area, the depth of the snow increases considerably away from the coast. Ice: Around mid-September, water bodies freeze across the North Slope, with an average maximum thickness of 1.80 m at the end of winter. By the middle of January, the ice is thick enough to support a loaded C-130 Hercules or a D-8 tractor. Ground water: There is very little liquid ground water in the coastal plain, but there is ground ice underlying the surface, which can't be used as a water supply. Research - Geologic History Moore, T.E., Wallace, W.K., Bird, K. J., Karl, S.M., Mull, C.G., and Dillon, J.T., 1994, Geology of northern Alaska, in Plafkler, G., and Berg, H.C., eds., The Geology of Alaska: Boulder, Colorado, Geological Society of America, The Geology of North America, v. G-1. BIRD, K.J. (1999). Geographic and Geologic Setting. In The Oil and Gas Resource Potential of the 1002 Area, Arctic National Wildlife Refuge, Alaska. By ANWR Assessment Team, U.S. Geological Survey Open-File Report 98-34. Geographic Placement The 1002 area of the Arctic National Wildlife Refuge is a 1.5-million-acre area in northeastern Alaska. It is bounded on the east by the Canning and Staines Rivers, on the north by the Beaufort Sea, on the east by the Aichilik River and the Canadian border, and to the south by Brooks Range. Most of the 1002 area lies within the Arctic Coastal Plain physiographic province, a marshy area that slopes gradually towards the Arctic Ocean on the north. A small part along the southern margin that constitutes less than 5% of the total area lies within the Arctic Foothills physiographic province, a series of hills and ridges that descend from more than 500 m in the Brooks Range to 300 m in elevation to the northern foreland. Beaches, low steep cliffs, barrier islands, shallow lagoons, and river deltas form the coast of the 1002 area, with hills rising to more than 300 m in the south. Many rivers and stream flow between these hills towards the Arctic Ocean. Origin The North Slope and its continental shelves, Brooks Range and the northeaster part of Siberia are considered to form the Arctic Alaska microplate, a small lithospheric plate with boundaries that are not clearly known. One hypothesis for the plate tectonic history of northern Alaska suggests that the region was originally next to the Canadian Arctic Islands. Creation of oceanic crust in the Canada basin during the Jurassic and Early Cretaceous caused the microplate to rotate 60 degrees counter clockwise, placing it in its current position. Surface Geology Nearly all of the surface of the 1002 area is covered by a thin layer, less than 30 m thick, of unconsolidated, frozen silt- to gravel-sized sediments of nonmarine origin. They originated from the erosion of the Brooks Range during the late Cenozoic. The surface exposures of rock formations inside the 1002 area are mostly restricted to deposits of the Sagavanirktok, Jago River, and Canning Formations of Tertiary age. There are some smaller outcrops of Hue Shale, pebble shale unit, and Kingak Shale from the Cretaceous and the Jurassic. To the east of the Sadlerochit Mountains, in the southern border of the 1002 area, some of the oldest exposures, of limestones from the Mississippian Lisburne Group, are found. Subsurface Structure Tectonics: During the rifting that separated northern Alaska from the Canadian Arctic Island, the Barrow arch, a structural high, was formed. The northern side of the Barrow arch formed the continental margin, while the southern flank received the thrust of the formation of the Brooks Range orogen. The part of the 1002 area located to the south and east of the Marsh Creek anticline and north of 69-degrees is the Brooks Range orogen. The Brooks Range is more than 1000 km long and up to 300 km wide, and the distribution and character of its major structures is not symmetrical. Deformations in this region occurred during the Cenozoic era, forming both east-northeastward and eastward structures. Parts of Jurassic to Cretaceous shales, Mississippian shales, and of a horizon in the pre-Mississippian basement rocks were separated from their source due to extreme folding and compression. The structure of the Brooks Range is formed by a series of broad anticlines with a core of pre-Mississippian rocks and younger rocks deformed on the borders. To the north of the Brooks Range, the structure, called thin-skinned deformation, is composed of numerous folds and faults developed in rocks of Cenozoic and Mesozoic age. Several broad domes are present in pre-Mississippian rocks in that area. Stratigraphy The stratigraphic record of the North Slope is divided into three sequences: Franklinian, Ellesmerian and Brookian. The Franklinian sequence comprises a thick succession of mainly sedimentary rocks with a minor amount of igneous rocks of Cambrian to Devonian age that lie beneath the pre-Mississippian unconformity, where a gap in the geologic record exists. Two separate layers of rock are present in northern Alaska. The shallow marine carbonates are composed of rocks of Proterozoic age and rocks of Lower Devonian age, separated by unconformities where Silurian strata are missing. They are composed of quartzite (metamorphic rock consisting of quartz grains, formed by recrystalization of sandstone), argillite compact rock derived from mudstone or shale, product of weak metamorphism), and basalt (dark-colored igneous rock), with intrusions of sandstone (the consolidate equivalent of sand, with 85-90% quartz), and shale (fine-grained sedimentary rock, formed by clay, silt or mud). The deeper marine layers include quartzite, conglomerate, phyllite (metamorphic rock, finer than schist), argilite, limestone (sedimentary rock formed by calcium carbonates), and granite (light-colored, coarse-grained igneous rock). The compression, uplift and erosion of this sequence during the Ellesmerian orogeny formed the pre-Mississippian unconformity. The Ellesmerian sequence is hundreds of meters thick, and is composed of layers of marine and nonmarine sedimentary rocks of Middle Devonian to Triassic age, that rests on top of the pre-Mississippian unconformity. The lower unit of this sequence is the Endicott Group, which, in the 1002 area, consists of Mississippian coal-bearing sandstone, conglomerate, and shale of the Kekiktuk Conglomerate and Kayak Shale, of Devonian and Mississippian age. The Kekiktuk Conglomerate is a proven oil-bearing reservoir. Large amounts of limestone and dolomine of the Lisburne Group were deposited in the North Slope up to a thickness of 500 to 1000 meters during the Mississippian and Pennsylvanian. It is separated from the overlying Sadlerochit Group by an unconformity formed during the Middle Pennsylvanian to Early Permian in when sea level fell. Water resources Snow: The North Slope is covered in snow from October to May of every year, and while snow might fall during any month, the precipitation during the summer is mainly rain. In spring, melting snow is the main source of water for lakes and streams in that region, and water stored in snowdrifts is released slowly and provides water for them during the summer. In the 1002 area, the depth of the snow increases considerably away from the coast. Ice: Around mid-September, water bodies freeze across the North Slope, with an average maximum thickness of 1.80 m at the end of winter. By the middle of January, the ice is thick enough to support a loaded C-130 Hercules or a D-8 tractor. Ground water: There is very little liquid ground water in the coastal plain, but there is ground ice underlying the surface, which can't be used as a water supply. Summary of the Geographic and Geologic Setting chapter by Kenneth J. Bird, Chapter GG in the USGS Open File Report 98-34 Intro: - 1.5 milllion acres - 105 miles east west, varying from 16-40 miles north south - bounded on the west by Canning and Stains River, North by the Beaufort Sea, east by Archilik River, and South by township lines and approximately the 1000 ft. elevation contour. - 100,000 acres are owned by Native Alaskans (Kaktovik Inupiat Corporation). The village of Kaktovik, population 200, is in the 1002 region on Barter Island. Only village in ANWR. Geological History: - "Developement of Devonian to Triassic south-facing (in present-day coordinates) passive continental margin." - "Northern Part- margin rifted in Jurassic to early cretacious time for an unknown parent continent" - "Coeval with the North, and arc-continent collision occured in the south, producing and orogenic land mass and adjacent foreland basin." - "As the foreland basin filled, continuing deformation resulted in a foreland fold and thrust belt." - "Youngest foreland basin sediments, where fold and thrust belt intersects and overrides the earlier formed rift margin and when the deformatioin and related sedimentation continues to present." - More geologically comples that anywhere in Northern Alaska. - Part of the North Slope geologic provinces. - Petroleum-prospective rocks aer restricted to mostly the Mississippiand and younger rocks. - same as in Prudoe Bay and Mackenzie Delta region of Canada Geography - Mostly lies within the Artic Coastal Plain physiographic province - Area is treeless, tundra covered and 99% wetland - foothills(95%), river flooded plains(25%), hilly coastal plains(22%), lagoons and oceans(5%), thaw lake plains(5%), mountains (less than 1%) Plate Tectonic Setting - part of small continental fragment call Artic Alaska microplate - history-(contreversial) most hypothesises- Cretacous rifting and the opening of the oceanic Canadian basin of the Artic ocean. Surface Geology - 95% covered by "a veneer of unconsolidated, frozen sediments of late cenozoic (mostly Quaternary) age, generally less than 100 ft thick. Petroleum Systems of the North Slope: Ellesmerian: Source rocks: type II kerogen - Shublik Formation (gas) - Kingak Shale (gas) - Pebble shale unit Reservoir rocks: - Endicott Group - Sedlerochit Group (quartz-rich conglomerate sandstone) - Kuparuk River Formation of Jamison - Lisburne Group (carbonate) Overburden (to mature source rocks): - Brookian sequence (deltaic deposits) Type of hydrocarbons: - Low gravity (med to heavy hydrocarbons) - High sulfur content Torok-Nanushuk (North East North Slope): Source rocks: type III kerogen - Torok Formation - Pebble shale unit Reservoir rocks: -Nanushuk Formation (sandstones, derived from formation of Brooks Range) Overburden (Brookine sequence): - Colville Group (shales) - Sagavanirktok Formation Types of hydrocarbon: - High gravity (med to light hydrocarbons) - Low sulfur content Hue-Sagavanirktok (Point Thomson to Canadian border): Source rocks: type II kerogen - Hue Shale Other rocks (either overmature or with type III kerogen -gas prone-) - Shublik Formation - Kingak Shale - Pebble shale unit Reservoir rock: - Sagavaniktok Formation - Canning Formation
Team 1 - m2007-1@mit.edu