Geology of the Northwest Territories

The geology of the Northwest Territories has been mapped in different quadrangles by the Canadian government. The region has some of the oldest rocks in the world and among the oldest in North America, formed from several sections of stable craton continental crust, including the Slave Craton, Rae Craton and Hearne Craton. These rocks form the Archean and Proterozoic Precambrian basement rock of the region and are the subject of extensive research to understand continental crust and tectonic conditions on the early Earth.

Geologic History, Stratigraphy & Tectonics

The Hearne Craton and Rae Craton are underlain by Archean metasedimentary and metavolcanic rocks. Quartz arenite in the Rae Craton has been interpreted as possible passive margin or rift deposits. Around the world, greenstone belts are a hallmark of ancient Precambrian rocks. The Ennadai-Rankin greenstone belt is the second largest in Canada and displays felsic volcanic and volcaniclastic rocks, as well as mafic rocks reaching greenschist grade on the sequence of metamorphic facies. Laminations in ironstone and pelite formations suggest that the mafic volcanic rocks deposited on the low energy slope of a volcanic plateau, away from wave action. Because of the enormous time distance from the Archean, exact interpretations are less reliable.[1]

In the late Proterozoic, the region was affected by the Wopmay orogeny. Along the edge of the Archean Slave Craton, a 1.1 kilometre thick wedge of carbonates formed the Rocknest Formation, which thins to the east. The Slave Craton (also known as the Slave Province) is smaller than the vast neighboring Superior Province, which extends southward to the Great Lakes. By contrast with the Superior Province, the Slave Province has more sedimentary rocks, more felsic than mafic rocks, more potassium-rich granite and gold and base-metal mineralization.[2] Geologists have inferred ancient sea floor spreading in the western part of the province from dikes and mafic lava flows, overlain by deep ocean turbidite deposits. These rocks are believed to be the remains of oceanic crust that ended up preserved, surrounded on all sides by felsic volcanic rocks and granitoid plutons.[3] In the area of Snofleld Lake in the northern part of the Slave Province, the remains of Archean stromatolites are preserved in a dolomite unit between felsic volcanic and greywacke-mudstone turbidites, some of the earliest evidence of life, forming in the shallows around volcanic islands.[4]

Around 1.27 billion years ago in the Proterozoic, a series of major magmatic events affected the region, referred to as "Mackenzie magmatic event," by some geologists. In the Coppermine River Province, tholeiite flood basalts emplaced at the same time over a rapid span of five million years. Strontium-neodymium-lead analysis indicates that the rocks included older, partially melted basement rocks.[5]

In the Neoproterozoic, the four kilometre thick Mackenzie Mountains Supergroup deposited in a poorly understood basin. Hydrothermal fluids emplaced base metals into these deposits, likely during rifting that lasted into the Paleozoic.[6]

Paleozoic (541-251 million years ago)

Marine deposition was common across much of the area in the Paleozoic. Within the Mackenzie Basin, tabulate and rugose corals grew formed the Horn Plateau Formation—a group of isolated reefs from the Devonian fed by nutrients from eroding Canadian Shield rocks and offshore upwelling in the ocean.[7] The Selwyn Basin, which now spans into the Yukon Territory formed at the same time and accumulated graptolite fossils and bitumen.[8]

The siliclastic, fossiliferous wackestone and mudstone of the Ordovician Bad Cache Rapids Formation record a shallow shelf environment on Southampton Island. This unit is overlain by the Ashgill Boas River Formation carbonaceous mudstone and oil shale, Churchill River Formation coral-bearing wackestone and the Sixteen Mile Brook oil shale.[9]

Mesozoic (251-66 million years ago)

In the Mesozoic, kimberlite pipes intruded Archean basement rock in places beginning around 75 million years ago and continuing into the Cenozoic in the Ekati area.[10]

Sedimentation continued in many areas into the Mesozoic. On Banks Island, manganese spherulites with rhodochrosite, iron-manganese oxides and dolomite mark the boundary between the Christopher and Kanguk sedimentary formations from the Cretaceous.[11]

Cenozoic (66 million years ago-present)

In the early Cenozoic, changes in regional structural geology led to widespread erosion and fission track analysis of apatite indicates that in the Beaufort-Mackenzie area, rocks cooled from temperatures around 110 degrees Celsius after one mile of rock eroded above them in the early Eocene.[12] The Northwest Territories was heavily glaciated during the Pleistocene. In the Mackenzie Mountains, moraine glacial till overlies older Paleogene gravel, paleosols and different till shed off of mountains.[13]

In the vicinity of the Mackenzie River delta and Sitidgi Lake till and sediments formed into the unglaciated Eskioma Lakes area. The Mackenzie delta formed as alluvium drowned valleys. Thermokarst and an ice-cored landscape took shape in the early Holocene.[14]

Gas Hydrates

Northern Canada and the Northwest Territories are famous for gas hydrates, also known as methane clathrate—methane gas frozen in thick sediments, which might hypothetically lead to intense climate change if they melted. Recognized from bore holes, gas flow during drilling or seismic data, it was not until March and April, 1993 that samples were recovered from a 451 meter deep hole in the Mackenzie Delta.[15]

References

  1. Aspler, Lawrence B.; Chiarenzelli, Jeffrey R. (1996). "Stratigraphy, sedimentology and physical volcanology of the Henik Group, central Ennadai-Rankin greenstone belt, Northwest Territories, Canada: late Archean paleogeography of the Hearne Province and tectonic implications". Precambrian Research. 77 (1–2): 59–89. doi:10.1016/0301-9268(95)00045-3.
  2. Padgham, W. A.; Fyson, W. K. (1992). "The Slave Province: a distinct Archean craton". Canadian Journal of Earth Sciences. 29 (10): 2072–2086. doi:10.1139/e92-165.
  3. Fyson, W. K.; Helmstaedt, H. (1988). "Structural patterns and tectonic evolution of supracrustal domains in the Archean Slave Province, Canada". Canadian Journal of Earth Sciences. 25 (2): 301–315. doi:10.1139/e88-032.
  4. Henderson, John B. (1975). "Archean Stromatolites in the Northern Slave Province, Northwest Territories, Canada". Canadian Journal of Earth Sciences. 12 (9): 1619–1630. doi:10.1139/e75-144.
  5. Dupuy, C.; Michard, A.; Dostal, J.; Dautel, D.; Baragar, W. R. A. (1992). "Proterozoic flood basalts from the Coppermine River area, Northwest Territories: isotope and trace element geochemistry". Canadian Journal of Earth Sciences. 29 (9): 1937–1943. doi:10.1139/e92-151.
  6. Turner, Elizabeth C.; Long, Darrel G.F. (2008). "Basin architecture and syndepositional fault activity during deposition of the Neoproterozoic Mackenzie Mountains supergroup, Northwest Territories, CanadaNorthwest Territories Geoscience Office Contribution 0040". Canadian Journal of Earth Sciences. 45 (10): 1159–1184. doi:10.1139/E08-062.
  7. Corlett, Hilary; Jones, Brian (2011). "Ecological controls on Devonian stromatoporoid-dominated and coral-dominated reef growth in the Mackenzie Basin, Northwest Territories, Canada". Canadian Journal of Earth Sciences. 48 (12): 1543–1560. doi:10.1139/e11-056.
  8. Riediger, C.; Goodarzi, F.; MacQueen, R. W. (1989). "Graptolites as indicators of regional maturity in lower Paleozoic sediments, Selwyn Basin, Yukon and Northwest Territories, Canada". Canadian Journal of Earth Sciences. 26 (10): 2003–2015. doi:10.1139/e89-169.
  9. Dewing, Keith; Copper, Paul (1991). "Upper Ordovician stratigraphy of Southampton Island, Northwest Territories". Canadian Journal of Earth Sciences. 28 (2): 283–291. doi:10.1139/e91-027.
  10. Nowicki, Tom; Crawford, Barbara; Dyck, Darren; Carlson, Jon; McElroy, Ross; Oshust, Peter; Helmstaedt, Herb (2004). "The geology of kimberlite pipes of the Ekati property, Northwest Territories, Canada". Lithos. 76 (1–4): 1–27. doi:10.1016/j.lithos.2004.03.020.
  11. Miall, Andrew D. (1974). "Manganese Spherulites at an Intra-Cretaceous Disconformity, Banks Island, Northwest Territories". Canadian Journal of Earth Sciences. 11 (12): 1704–1716. doi:10.1139/e74-168.
  12. O'Sullivan, Paul B.; Lane, Larry S. (1997). "Early Tertiary thermotectonic history of the northern Yukon and adjacent Northwest Territories, Arctic Canada". Canadian Journal of Earth Sciences. 34 (10): 1366–1378. doi:10.1139/e17-109.
  13. Duk-Rodkin, A.; Barendregt, R. W.; Tarnocai, C.; Phillips, F. M. (1996). "Late Tertiary to late Quaternary record in the Mackenzie Mountains, Northwest Territories, Canada: stratigraphy, paleosols, paleomagnetism, and chlorine - 36". Canadian Journal of Earth Sciences. 33 (6): 875–895. doi:10.1139/e96-066.
  14. "Quaternary geology of the Tuktoyaktuk coastlands, Northwest Territories (Technical Report) | ETDEWEB". osti.gov. Retrieved 2018-11-10.
  15. Dallimore, S. R.; Collett, T. S. (1995). "Intrapermafrost gas hydrates from a deep core hole in the Mackenzie Delta, Northwest Territories, Canada | Geology". Geology. 23 (6): 527. doi:10.1130/0091-7613(1995)023<0527:IGHFAD>2.3.CO;2.

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