Purcell Supergroup

The Purcell Supergroup is composed primarily of argillites, carbonate rocks, quartzites, and mafic igneous rocks of late Precambrian (Mesoproterozoic) age. It is present in an area of about 15,000 km2 (5,800 sq. mi.) in southwestern Alberta and southeastern British Columbia, Canada, and it extends into the northwestern United States where it is called the Belt Supergroup. It was named for the Purcell Mountains of British Columbia by R.A. Daly in 1912.[2] Fossil stromatolites and algal structures are common in some of the Purcell Supergroup rocks,[3][4] and the Sullivan ore body at Kimberley, British Columbia, a world-class deposit of lead, zinc, and silver, lies within the Alderidge Formation in the lower part of the Purcell.[5]

Purcell Supergroup
Stratigraphic range: Mesoproterozoic
TypeGeological supergroup
Sub-unitsMany
UnderliesWindermere Supergroup
OverliesCanadian Shield
Area15,000 km2 (5,800 sq. mi.)
Thicknessmore than 10,000 m (3,200 ft)[1]
Lithology
PrimaryArgillite, dolomite, quartzite
OtherLimestone, igneous rocks
Location
Region Alberta
 British Columbia
Country Canada
Type section
Named forPurcell Mountains
Named byR.A. Daly, 1912.[2]

Spectacular outcrops of Purcell and Belt Supergroup rocks can be seen in Glacier National Park in northwestern Montana[6] and Waterton Lakes National Park in southwestern Alberta.[7]

Stratigraphy and lithology

The Purcell Supergroup consists primarily of argillites, carbonate rocks (limestone and dolomite), and quartzites, and includes localized occurrences of igneous rocks (mafic lava flows, tuffs, pillow basalts, and gabbroic and dioritic sills and dykes). Sedimentary structures are well preserved in the Purcell rocks despite their great age.[1]

In the southern Canadian Rockies (Waterton Park area), the supergroup is subdivided as follows:

Geological unitLithologyEnvironment of DepositionMaximum
Thickness
Reference
Roosville Formationgreen and grey argillite; dolomitic argillite, siltstone and sandstone; argillaceous and stromatolitic dolomite; mudcracks and ripple marks are common.shallow marine (peritidal)1,300 m (4,270 ft) [1][8][9]
Phillips Formationred, thin-bedded quartz sandstone; siltstone interbedded with argillite and conglomerate; mudcracks and ripple marks are common.marginal marine to nonmarine200 m (660 ft)[1][8][9]
Gateway Formationred siltstone and argillite; green argillite; dolomitic argillite; dolomitic sandstone; dolomite; and sandy dolomite; casts of salt crystals, mudcracks, ripple marks, and rip-up clasts are locally abundant.marginal marine1,350 m (4,430 ft) [1][8][9]
Sheppard Formationlight grey dolomite and stromatolitic dolosmite; red dolomitic siltstone and sandstone; dolomitic argillite.shallow marine275 m (900 ft) [1][8][9]
Purcell Lavadark green and reddish green to purple chloritized mafic lava flows, pillow basalts, gabbroic sills and dikes; amygdules of quartz, chlorite, and calcite are common.shallow marine150 m (490 ft)

[1][8][9]

Siyeh Formationargillaceous limestone and dolomite; black and green argillite; dolomitic quartzite; stromatolitic dolomite.marginal marine790 m (2,590 ft)[1][8][9]
Appekunny Formationgreen and maroon argillite; white, grey, green, and pale red sandstone; quartz-pebble conglomerate.marginal marine1,000 m (3,280 ft)[1][8][9]
Altyn Formationgrey, thin-bedded argillaceous limestone and dolomite; massive sandy dolomite and stromatolitic dolomite; dark grey to black argillite.shallow marine300 m (980 ft)[1][8][9]
Waterton Formationgrey, green and red argillaceous dolomite; banded and streaked limestone and dolomite; grey and green, thin-bedded argillite.marine250 m (820 ft)[1][8][9]
Tombstone Mountain Formationdark grey argillite; dolomitic argillite; argillaceous dolomite and limestone.marine175 m (570 ft)[1][8][9]
Haig Brook Formationlight colored, cliff-forming sequence of dolomite; banded and streaked limestone and dolomite; minor argillite; base of formation is not exposed.marine145 m (480 ft)[1][8][9]

In the southern Purcell Mountains (Cranbrook area), the supergroup is subdivided as follows:

Geological unitLithologyEnvironment of DepositionMaximum
Thickness
Reference
Roosville Formationdolomitic argillite; siltstone; sandstone; and argillaceous and stromatolitic dolomite.intertidal300 m (980 ft) [4]
Phillips Formationred, thin-bedded quartz sandstone; siltstone interbedded with argillite; ripple marks and mud cracks are abundant locally.shallow water to subaerial150 m (490 ft)[4]
Gateway Formationgrey-green, red, and purple siltstone; dolomitic siltstone; minor interbeds of argillite; casts of salt crystals, mudcracks, ripple marks, and rip-up clasts are locally abundant.lagoonal1,350 m (4,430 ft) [4]
Sheppard Formationlight grey stromatolitic dolomite, interbedded with dolomitic siltstone and argillite; stromatolite mounds up to 10 m (30 ft) thick; mudcracks, ripple marks, and rip-up clasts are locally abundant; casts of salt crystals are rare.intertidal125 m (410 ft) [4]
Intrusive rocksfine- to coarse-grained sills and dikes of gabbro and diorite intrude the Aldridge to Van Creek Formations.intrusive

[4]

Nichol Creek Formationgreen and purple argillite and siltstone; green volcanic sandstone and tuff interlayered with green or maroon, chloritized and sericitized basaltic to andesitic lavas, some with amygdules of quartz and chlorite.subaerial750 m (2,460 ft)[4]
Van Creek Formationgreen to purple argillite and siltstone; mud cracks, ripple marks, and rip-up clasts are locally abundant.intertidal420 m (1,380 ft)[4]
Kitchner Formationcalcareous and dolomitic siltstone and argillite; silty dolomite and limestone; minor quartzite.shallow subtidal
(intertidal at base)
1,900 m (6,230 ft)[4]
Creston Formationgreen, grey, and purple siltstone and argillite; mud cracks, ripple marks, and rip-up clasts are locally abundant.shallow subtidal
(intertidal at top)
2,350 m (7,710 ft)[4]
Aldridge Formationfine-grained quartzite; argillaceous quartzite; rusty-weathering grey siltstone; dark grey argillite; base of formation not exposed.marine (subtidal at top)>4,200 m (13,780 ft)[4]

Environment of deposition

The Purcell Supergroup was probably deposited in subsiding deltaic to marine environments along the margin of the North American craton,[10] possibly in an intracratonic basin where North America and another landmass were joined in a supercontinent called Columbia/Nuna.[11] Deposition occurred during the Mesoproterozoic era, much of it probably between about 1470 and 1400 Ma (million years) ago.[12][13]

Distribution and thickness

In Canada, the Purcell Supergroup is present in an area of about 15,000 km2 (5,800 sq. mi.) that reaches from the southern Purcell Mountains in southeastern British Columbia to the southern Canadian Rockies in the southwestern Alberta.[1] It extends southward into the United States (western Montana, northern Idaho, northwestern Washington, and western Wyoming) where it is called the Belt Supergroup.[14] It reaches a maximum thickness of more than 10,000 metres (32,000 ft) in the Purcell Mountains.[1]

Relationship to other units

The Purcell Supergroup is equivalent to the Belt Supergroup of the northwestern United States. The base of the Purcell is not exposed in Canada, but it is inferred to rest unconformably on the Canadian Shield. The Purcell is unconformably overlain by the Neoproterozoic Windermere Supergroup in most areas, or by younger Cambrian or Devonian formations where the Windermere is absent.[1]

Economic resources

The now-closed Sullivan Mine at Kimberley, British Columbia, worked a world-class sedimentary exhalative (SedEx) deposit that is hosted in the lower part of the Purcell Supergroup. During the life of the mine, the Sullivan ore body is reported to have yielded 8,412,077 tonnes of lead, 7,944,446 tones of zinc, and 9,264 tonnes of silver, as well as significant quantities of tin and other metals.[5]

References

  1. Glass, D.J. (editor) 1997. Lexicon of Canadian Stratigraphy, vol. 4, Western Canada including eastern British Columbia, Alberta, Saskatchewan and southern Manitoba. Canadian Society of Petroleum Geologists, Calgary, 1423 p. on CD-ROM. ISBN 0-920230-23-7.
  2. Daly, R.A. 1912. Geology of the North American Cordillera at the Forty-ninth parallel. Geological Survey of Canada, Memoir 38, p. 119-136.
  3. O'Connor, M.P. 1972. Classification and environmental interpretation of the cryptalgal organosedimentary "Molar-Tooth" structure from the Late Precambrian Belt-Purcell Supergroup. Journal of Geology, vol. 80, no. 5, p. 592-610.
  4. McMechan, M.E. 1981. The Middle Proterozoic Purcell Supergroup in the southwestern Rocky and southeastern Purcell Mountains, British Columbia, and the initiation of the Cordilleran Miogeocline, southern Canada and adjacent United States. Bulletin of Canadian Petroleum Geology, vol. 29, no. 4, p. 583-621.
  5. Lydon, John W. "Geology and metallogeny of the Belt-Purcell Basin. In: Goodfellow, W.D. (ed.), Mineral deposits of Canada: a synthesis of major deposit types, district metallogeny, the evolution of geological provinces, and exploration methods. Geological Association of Canada, Mineral Deposits Division, Special Publication no. 5, p. 581-607". Retrieved 29 April 2018.
  6. Alt, D.D. and Hyndman, D.W. 1986. Roadside geology of Montana. Mountain Press Publishing Co., Missoula, Montana, 427 p. ISBN 0-87842-202-1,
  7. Gordy, P.L., Frey, F.R. and Norris, D.K. 1977. Geological guide for the CSPG 1977 Waterton-Glacier Park Field Conference. Canadian Society of Petroleum Geologists, Calgary, Alberta, 93 p.
  8. Prior, G. J., Hathaway, B., Glombick, P.M., Pana, D.I., Banks, C.J., Hay, D.C., Schneider, C.L., Grobe, M., Elgr, R., and Weiss, J.A. (2013). "Bedrock Geology of Alberta (Legend). Alberta Geological Survey, Map 600". Archived from the original on 2016-06-26. Retrieved 2016-06-20.CS1 maint: multiple names: authors list (link)
  9. Alberta Geological Survey, 2013. "Alberta Table of Formations; Alberta Energy Regulator". Archived from the original on 1 May 2018. Retrieved 1 May 2018.
  10. Hein, F.J. and McMechan, M.E. 1994. "Atlas of the Western Canada Sedimentary Basin (Mossop, G.D. and Shetsen, I., compilers), Chapter 6: Proterozoic and Lower Cambrian strata of the Western Canada Sedimentary Basin". Retrieved 11 April 2018.CS1 maint: multiple names: authors list (link)
  11. Schieber, J., 1989. The origin of the Neihart Quartzite, a basal deposit of the mid-Proterozoic Belt Supergroup, Montana, USA. Geological Magazine, v. 126, p. 271-281.
  12. Evans, K.V., Aleinikoff, J.N., Obradovich, J.D. and Fanning, C.M. 2000. SHRIMP U-Pb geochronology of volcanic rocks, Belt Supergroup, western Montana: evidence for rapid deposition of sedimentary strata. Canadian Journal of Earth Sciences, v. 37, p.1287-1300.
  13. Halpin, Jacqueline A.; Jensen, Torsten; McGoldrick, Peter; Meffre, Sebastien; Berry, Ron F.; Everard, John L.; Calver, Clive R.; Thompson, Jay; Goemann, Karsten; Whittaker, Joanne M. (2014). "Authigenic monazite and detrital zircon dating from the Proterozoic Rocky Cape Group, Tasmania: Links to the Belt-Purcell Supergroup, North America". Precambrian Research. 250: 50–67. doi:10.1016/j.precamres.2014.05.025.
  14. Lori Tapanila and Paul Link. "Mesoproterozoic Belt Supergroup". Digital Geology of Idaho. Idaho State University, Department of Geosciences. Retrieved 16 September 2016.
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