141 21.5 Western Canada during the Cenozoic

Two additional relatively small terranes collided with North America early in the Cenozoic. At around 55 Ma, metamorphosed sedimentary and volcanic rocks of the Pacific Rim Terrane were forced a few tens of kilometres underneath the west coast of Vancouver Island (Figure 21.26). These rocks are distributed along the west coast of the island and in the area around Victoria (Figure 21.27). At around 42 Ma, sea-floor pillow basalt and gabbro of the Crescent Terrane accreted to the southern margin of Vancouver Island and also to the adjacent part of Washington State. These terranes are shown as Outboard terranes in Figure 21.14.

Figure 21.26 East-west cross-section showing the accretion of the Pacific Rim and Crescent Terranes beneath Vancouver Island, and the ongoing subduction of the Juan de Fuca Plate. The dashed lines are inactive faults. [SE after Geological Survey of Canada]
Figure 21.26 East-west cross-section showing the accretion of the Pacific Rim and Crescent Terranes beneath Vancouver Island, and the ongoing subduction of the Juan de Fuca Plate. The dashed lines are inactive faults. [SE after Geological Survey of Canada]

 

Figure 21.27 The distribution of Pacific Rim and Crescent Terrane rocks on Vancouver Island [SE after Geological Survey of Canada]
Figure 21.27 The distribution of Pacific Rim and Crescent Terrane rocks on Vancouver Island [SE after Geological Survey of Canada]

The accretion of the Pacific Rim and Crescent Terranes had the effect of pushing Vancouver Island closer to the North American mainland, resulting in the uplift of the sediments deposited within the Nanaimo Basin to form islands in the Strait of Georgia (Figure 21.28) and mountains on Vancouver Island.

Figure 21.28 The Geoffrey Formation of the Nanaimo Group on Ruxton Island, B.C. [SE]
Figure 21.28 The Geoffrey Formation of the Nanaimo Group on Ruxton Island, B.C. [SE]

 

Following these events, the subduction of the Juan de Fuca Plate, which is a remnant of the former, much larger, Farallon Plate, was re-established at its current location farther to the west of Vancouver Island. This subduction, and that of the North America Plate beneath Alaska, has produced recently active volcanoes in Alaska, and all along the west coast from north of Vancouver Island to northern California (Figure 21.29). In southwestern B.C., there are several dormant volcanoes of Pleistocene age (including Garibaldi and Meager) that trend along a line that also passes through Mt. Baker in Washington State. About 40 km to the east is a trend of slightly older igneous complexes (Pliocene to Oligocene). The displacement between these belts could be explained by a westward shift in the position of the subduction zone over that time period.

Figure 21.29 The current plate situation along the western edge of northern North America. Blue lines are divergent boundaries, red lines are transform boundaries, and black lines with teeth are subduction boundaries. The dark red triangles are volcanoes. [SE]
Figure 21.29 The current plate situation along the western edge of northern North America. Blue lines are divergent boundaries, red lines are transform boundaries, and black lines with teeth are subduction boundaries. The dark red triangles are volcanoes. [SE]

The subduction and transform boundaries along this coast also generate relatively frequent earthquakes throughout this region, as illustrated in Exercise 11.1.

Figure 21.30 Oligocene to Pleistocene igneous complexes and volcanoes in southwestern B.C. and adjacent Washington [SE]
Figure 21.30 Oligocene to Pleistocene igneous complexes and volcanoes in southwestern B.C. and adjacent Washington [SE]

Sedimentation in the WCSB continued into the Cenozoic (Figure 21.22) with deposition of the Paskapoo Formation adjacent to the Rockies in Alberta (Figure 21.31), the Ravenscrag Formation in the Cypress Hills of southern Alberta and Saskatchewan, and the Turtle Hills Formation in southern Manitoba. All of these strata were deposited in terrestrial fluvial and deltaic environments, and all of them include coal deposits. Numerous mammalian (and other) fossils have been found in these rocks in Alberta and Saskatchewan. The mammals include primitive ungulates (ancestors to the deer and their relatives), a type of pangolin, a colugo (a gliding mammal that was possibly a primate ancestor), and some true primates in the suborder Plesiadapiformes, which became extinct and are not ancestors to any modern primates.

Figure 21.31 The Paskapoo Formation exposed on the banks of the Red Deer River, Alberta [https://commons.wikimedia.org/wiki/File:Paskapoo_Mudstones_Red_Deer.jpg]
Figure 21.31 The Paskapoo Formation exposed on the banks of the Red Deer River, Alberta [https://commons.wikimedia.org/wiki/File:Paskapoo_Mudstones_Red_Deer.jpg]

 

Exercises

Exercise 21.5 The Volume of the Paskapoo Formation

The area underlain by the Paleocene Paskapoo Formation is outlined in yellow on the map shown here. The Paskapoo ranges up to about 1,000 m thick, and contours of its thickness (known as isopachs) are shown. The average thickness is about 500 m, and the area covered by the formation is about 90,000 km2. This means that the rock has a volume of about 45,000 km3. The sediments of the Paskapoo were derived from the Paleocene Rocky Mountains, within the area shown in blue, which is about 60,000 km2.Volume-of-the-Paskapoo-Formation

1. What average depth of erosion would have been required within the source area to produce the 45,000 km3 of sediment, assuming that all of the eroded sediment ended up in the Paskapoo Formation?

2. The Paskapoo was deposited over a period of 4 million years from 62.5 Ma to 58.5 Ma. Assuming an average thickness of 500 m, what was the average rate of deposition (in mm/year) over that period?

[SE after Alberta Geological Survey]

Rocks younger than Paleocene (i.e., younger than 55 Ma) are relatively rare across the prairies, but there are widespread Eocene-aged volcanic and sedimentary rocks in central and southern B.C. The Kamloops Group includes the Tranquille Formation of lacustrine sediments (lake deposited), overlain by the Dewdrop Flats Formation of basaltic and andesitic volcanic flows and breccias. The Tranquille Formation includes the McAbee Beds and a number of other important sites with Eocene fossils (Figure 21.32).

Figure 21.32 The Tranquille Formation at the McAbee fossil site west of Kamloops, B.C. [SE]
Figure 21.32 The Tranquille Formation at the McAbee fossil site west of Kamloops, B.C. [SE]

 

The earliest Pleistocene glaciation in Canada started at about 2.64 Ma (late Pliocene) in the Klondike area of Yukon. This was part of the Cordilleran Ice Sheet. The Laurentide Ice Sheet started to form shortly afterward, and within 200,000 years had covered a large part of Canada and extended well into the United States. The Pleistocene glaciations had a major impact on the topography and geology of western Canada, creating extraordinary glacial erosion features in the mountainous regions of the west (Figure 21.33), and leaving enormous volumes of glacial sediment and glacial depositional features throughout the region (Figure 21.34).

Figure 21.33 Various glacial erosion features (top left) and glaciation at the Overlord Glacier, Coast Mountains, B.C. [Isaac Earle, used with permission]
Figure 21.33 Various glacial erosion features (top left) and glaciation at the Overlord Glacier, Coast Mountains, B.C. [Isaac Earle, used with permission]

 

Figure 21.34 A drumlin field with an esker (centre) in the Cree Lake area of northern Saskatchewan [NASA Landsat image, from Google Earth]
Figure 21.34 A drumlin field with an esker (centre) in the Cree Lake area of northern Saskatchewan [NASA Landsat image, from Google Earth]

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Physical Geology Copyright © 2015 by Steven Earle is licensed under a Creative Commons Attribution 4.0 International License, except where otherwise noted.

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