Mount Price (British Columbia)

Last updated

Mount Price
Red Mountain
Clinker Mountain
View towards Garibaldi Lake from Panorama Ridge (DSCF1842 - DSCF1844) (cropped).jpg
Mount Price behind Garibaldi Lake from Panorama Ridge
Highest point
Elevation 2,049 m (6,722 ft) [1]
Coordinates 49°55′03″N123°02′08″W / 49.91750°N 123.03556°W / 49.91750; -123.03556 [2]
Naming
Etymology Thomas E. Price [2]
Geography
Canada British Columbia relief location map.jpg
Red triangle with thick white border.svg
Mount Price
Location in British Columbia
Country Canada [3]
Province British Columbia [3]
District New Westminster Land District [2]
Protected area Garibaldi Provincial Park [4]
Parent range Garibaldi Ranges
Topo map NTS   92G14 Cheakamus River [2]
Geology
Rock age Less than 1.2 million years old [3]
Mountain type Stratovolcano [1]
Rock type(s) Andesite and dacite [3]
Volcanic belt Garibaldi Volcanic Belt [3]
Last eruption 15,000–8,000 years ago [5] [6]

Mount Price is a small stratovolcano in the Garibaldi Ranges of the Pacific Ranges in southwestern British Columbia, Canada. It has an elevation of 2,049 metres (6,722 feet) and rises above the surrounding landscape on the western side of Garibaldi Lake in New Westminster Land District. The mountain contains a number of subfeatures, including Clinker Peak on its western flank, which was the source of two thick lava flows between 15,000 and 8,000 years ago that ponded against glacial ice. These lava flows are structurally unstable, having produced large landslides as recently as the 1850s. A large provincial park surrounds Mount Price and other volcanoes in its vicinity. It lies within an ecological region that surrounds much of the Pacific Ranges.

Contents

Mount Price is associated with a small group of volcanoes called the Garibaldi Lake volcanic field. This forms part of the larger Garibaldi Volcanic Belt, a north−south trending volcanic zone that represents a portion of the Canadian Cascade Arc. Mount Price began its formation 1.2 million years ago and continued intermittently until sometime in the last 15,000 years. Although the mountain is not known to have been volcanically active for thousands of years, it could erupt again, which would potentially endanger the nearby populace. If this were to happen, relief efforts could be organized by teams such as the Interagency Volcanic Event Notification Plan who are prepared to notify people threatened by volcanic eruptions in Canada.

Geography

Mount Price is located south of Whistler on the western side of Garibaldi Lake in New Westminster Land District. [2] It lies within the Pacific Ranges Ecoregion, a mountainous region of the southern Coast Mountains characterized by high, steep and rugged mountains made of granitic rocks. Much of this ecoregion encompasses the Pacific Ranges in southwestern British Columbia, although it also includes the northwesternmost portion of the Cascade Range in Washington state. Several coastal islands, channels and fjords occur along the western margin of the Pacific Ranges Ecoregion. The Pacific Ranges Ecoregion is part of the Coast and Mountains Ecoprovince which forms part of the Humid Maritime and Highlands Ecodivision. [7]

Topographic map of the Garibaldi Lake area depicting Mount Price and adjacent peaks Garibaldi Lake and Mount Price topographical map.jpg
Topographic map of the Garibaldi Lake area depicting Mount Price and adjacent peaks

The Pacific Ranges Ecoregion is subdivided into seven ecosections, the Eastern Pacific Ranges Ecosection being the main ecosection at Mount Price. This ecosection is characterized by a rugged landscape of mountains that increase in elevation from south to north; the northern summits contain large icefields. A transitional climate between coastal maritime and interior continental climates dominates the Eastern Pacific Ranges Ecosection. It is characterized by little precipitation and mild temperatures due to Pacific air often passing over this area. During winter, cold Arctic air invades from the Central Interior, resulting in extreme cloud cover and snow. A number of other volcanoes are situated within the Eastern Pacific Ranges Ecosection. This includes Mount Meager, which lies near the headwaters of the Lillooet River, and Mount Garibaldi and Mount Cayley, which lie in the Squamish River watershed. [7]

Several rivers flow through the Eastern Pacific Ranges Ecosection, including the Fraser and Coquihalla rivers on its eastern side, the Cheakamus, Squamish and Elaho rivers on its western side and the Lillooet River in the middle. Coastal western hemlock forests dominate nearly all the valleys and lower slopes of this ecosection, the upper slopes containing subalpine mountain hemlock forests and, to a lesser extent, Engelmann spruce and subalpine fir forests. Alpine vegetation lies just above the subalpine forests, which is normally overlain by barren rock. [7] Wildlife such as grey jays, chipmunks, squirrels, flickers, deer, mountain goats, wolverines, cougars and grizzly and black bears are locally present. [8] The communities of Whistler, Pemberton, Mount Currie, Hope and Yale are situated within the Eastern Pacific Ranges Ecosection, all of which are connected to the Lower Mainland by a network of highways. [7]

Geology

Mount Garibaldi with Mount Price and Clinker Peak in the left-centre Trips 03 - Brandywine - Mt Garibaldi (4435874720).jpg
Mount Garibaldi with Mount Price and Clinker Peak in the left-centre

Mount Price is one of the three principal volcanoes in the southern segment of the Garibaldi Volcanic Belt, the other two being Mount Garibaldi and The Black Tusk. [3] Mount Price is also part of the Garibaldi Lake volcanic field. This consists of several volcanoes and lava flows that formed in the last 1.3 million years; the oldest volcanic rocks are found at Mount Price and The Black Tusk. Several volcanic rocks with differing compositions are present in the Garibaldi Lake volcanic field. This includes andesite, dacite, basaltic andesite and basalt. [3] It is unknown when the last eruption occurred but it may have been in the early Holocene. [a] [1] [3] Although no hot springs are known in the Garibaldi area, there is evidence of anomalously high heat flow in Table Meadows just south of Mount Price and elsewhere. [10]

Like other volcanoes in the Garibaldi Volcanic Belt, Mount Price formed as a result of subduction zone volcanism. As the Juan de Fuca Plate thrusts under the North American Plate at the Cascadia subduction zone, it forms volcanoes and volcanic eruptions. [11] Unlike most subduction zones worldwide, there is no deep oceanic trench along the continental margin of Cascadia. There is also very little seismic evidence that the Juan de Fuca Plate is actively subducting. The probable explanation lies in the rate of convergence between the Juan de Fuca and North American plates. These two tectonic plates currently converge at a rate of 3 to 4 centimetres (1.2 to 1.6 inches) per year, only about half the rate of convergence from seven million years ago. This slowed convergence likely accounts for reduced seismicity and the lack of an oceanic trench. The best evidence for ongoing subduction is the existence of active volcanism in the Cascade Volcanic Arc. [3]

Structure

False colour image of Mount Price and associated lava flows Garibaldi Lake area map.jpg
False colour image of Mount Price and associated lava flows

Mount Price attains an elevation of 2,049 metres (6,722 feet) and is one of several Garibaldi Belt volcanoes that have been volcanically active throughout the Quaternary. [b] [1] [3] In contrast to most stratovolcanoes in Canada, Mount Price has a nearly symmetrical structure. [3] Its western slope is flanked by Clinker Peak, a 1,983-metre-high (6,506-foot) parasitic stratovolcano containing a breached volcanic crater. [1] [3] Oxidation of Mount Price's volcanic rocks has given the mountain a red colour. [12]

Mount Price stands within a cirque-like basin cut into the plateau on the south side of the valley of Garibaldi Lake. This basin consists of a wall of granite, inclosing the volcano on its west and southwest sides. It is now almost completely filled up by Mount Price, but some small areas of its floor are exposed on the north side. The basin likely formed as a result of glacial action as its north side appears to have been almost certainly glaciated. It might otherwise have been attributed to explosive volcanism, but there are no fragmental materials around its margin which would confirm this. [13]

Volcanic history

At least three phases of eruptive activity have been identified at Mount Price. [3] The first eruptive phase 1.2 million years ago deposited hornblende [c] andesite lava and pyroclastic rocks on the floor of the cirque-like basin after an Early Pleistocene [d] glacial event. [3] [16] During the Middle Pleistocene [e] about 300,000 years ago, volcanism of the second phase shifted westward and constructed the nearly symmetrical stratovolcano of Mount Price. Episodic eruptions during this phase of activity produced andesite and dacite lavas, as well as pyroclastic flows from Peléan activity. Later, the volcano was overridden by the Cordilleran Ice Sheet, which covered a large portion of western North America during glacial periods of the Quaternary. [3]

The Barrier is part of a thick lava flow that erupted from Clinker Peak between 15,000 and 8,000 years ago. The Barrier lava dam.jpg
The Barrier is part of a thick lava flow that erupted from Clinker Peak between 15,000 and 8,000 years ago.

After the Cordilleran Ice Sheet retreated from higher elevations less than 15,000 years ago, andesite eruptions of the third eruptive phase occurred from a satellite vent at Price Bay. [3] [5] [16] These eruptions resulted in the creation of a small lava dome or scoria cone on Mount Price's northern flank with an elevation of 1,788 metres (5,866 feet). [1] [5] [16] Possibly contemporaneous volcanism occurred at Clinker Peak with the eruption of two hornblende-biotite [f] andesite lava flows. [3] They are both at least 300 metres (980 feet) thick and 6 kilometres (3.7 miles) long, extending to the northwest and southwest. [3] [16] Their unusually large thickness is due to them ponding and cooling against the Cordilleran Ice Sheet when it still filled valleys at lower elevations. [16] Age estimates for this final volcanic phase have varied from 15,000 years ago to as recently as 8,000 years ago. [5] [6]

A prominent feature of the Clinker Peak lava flows are the levees that demarcate the lava channels. The northwest lava flow forms a volcanic dam known as The Barrier. [19] This retains the Garibaldi Lake system and has been the source of two large landslides in the past. The most recent major landslide in 1855–1856 resulted from failure along vertical rock fractures. [20] It travelled 6 kilometres (3.7 miles) down Rubble Creek to the Cheakamus River valley, depositing 30,000,000 cubic metres (1.1×109 cubic feet) of rock. [20] [21] The southwest lava flow is in the upper reaches of the Culliton Creek valley and forms Clinker Ridge. [6] [19] Both lava flows form steep cliffs; the current face of The Barrier is a result of the mid-19th century landslide. [6]

Volcanic hazards

Mount Price with Clinker Peak on the right and the forested Price Bay dome on the left Mount Price and the Table.jpg
Mount Price with Clinker Peak on the right and the forested Price Bay dome on the left

Mount Price is one of the four highest threat volcanoes in Canada situated within close proximity to major populations with critical civil and economic infrastructure, the other three being Mount Meager, Mount Garibaldi and Mount Cayley. [22] Although Plinian eruptions have not been identified at Mount Price, Peléan eruptions can also produce large amounts of volcanic ash that could significantly affect the nearby communities of Whistler and Squamish. Peléan eruptions might cause short and long term water supply problems for the city of Vancouver and most of the Lower Mainland. The catchment area for the Greater Vancouver watershed is downwind from Mount Price. An eruption producing floods and lahars could destroy parts of Highway 99, threaten communities such as Brackendale and endanger water supplies from Pitt Lake. Fisheries on the Pitt River would also be at risk. [19] Mount Price is also close to a major air traffic route; volcanic ash reduces visibility and can cause jet engine failure, as well as damage to other aircraft systems. [23] [24] These volcanic hazards become more serious as the Lower Mainland grows in population. [19]

Mount Price and Clinker Peak GaribaldiPP-MountPrice1.jpg
Mount Price and Clinker Peak

Because andesite is the main type of lava erupted from Mount Price, lava flows are a low to moderate hazard. [19] Andesite is intermediate in silica content, indicating it has a higher viscosity than basaltic lava but is less viscous than dacite or rhyolite lava. As a result, andesite lava flows typically move slower than basaltic lava flows and are less likely to travel as far from their source. Dacite and rhyolite lavas are normally too viscous to flow away from a volcanic vent, resulting in the formation of lava domes. [25] An exception is the 15-kilometre-long (9.3-mile) Ring Creek dacite lava flow from Opal Cone on the southeastern flank of Mount Garibaldi, a length that is normally attained by basaltic lava flows. [19]

Concerns about The Barrier's instability due to volcanic, tectonic or heavy rainfall activity prompted the provincial government to declare the area immediately below it unsafe for human habitation in 1980. [20] This led to the evacuation of the small resort village of Garibaldi nearby and the relocation of residents to new recreational subdivisions away from the hazard zone. [19] [20] The area below and adjacent to The Barrier has since been referred to as the Barrier Civil Defence Zone by BC Parks. Although landslides are unlikely to happen in the near future, warning signs are posted at the zone to make visitors aware of the potential danger and to minimize the chance of fatalities in the event of a slide. For safety reasons, BC Parks recommends visitors not to camp, stop or linger in the Barrier Civil Defence Zone. [8]

Monitoring

Like other volcanoes in the Garibaldi Lake volcanic field, Mount Price is not monitored closely enough by the Geological Survey of Canada to ascertain its activity level. The Canadian National Seismograph Network has been established to monitor earthquakes throughout Canada, but it is too far away to provide an accurate indication of activity under the mountain. It may sense an increase in seismic activity if Mount Price becomes highly restless, but this may only provide a warning for a large eruption; the system might detect activity only once the volcano has started erupting. [26] If Mount Price were to erupt, mechanisms exist to orchestrate relief efforts. The Interagency Volcanic Event Notification Plan was created to outline the notification procedure of some of the main agencies that would respond to an erupting volcano in Canada, an eruption close to the Canada–United States border or any eruption that would affect Canada. [27]

Human history

Protection

Mount Price with Garibaldi Lake in the foreground Garibaldi Lake and Mount Price.jpg
Mount Price with Garibaldi Lake in the foreground
Garibaldi Lake with Mount Price behind on the left Garibaldi Lake and Mount Price1.jpg
Garibaldi Lake with Mount Price behind on the left

Mount Price and its eruptive products lie within a conservation area called Garibaldi Provincial Park. [4] Founded in 1927 as a Class A provincial park, this wilderness park covers an area of 194,650 hectares (481,000 acres). Lying within its boundaries are a number of other volcanoes, such as Mount Garibaldi and The Black Tusk. Located 70 kilometres (43 miles) north of Vancouver in the glaciated Coast Mountains, Garibaldi Provincial Park contains diverse vegetation, iridescent waters and a rich geological history. The park also has abundant wildlife, such as squirrels, chipmunks, Canada jays and flickers. Garibaldi Provincial Park is named after Mount Garibaldi, which is in turn named after the Italian patriot and soldier Giuseppe Garibaldi. [8]

Naming

Mount Price has had at least three names throughout its history. It was originally named Red Mountain for its red appearance, but the date when this name was adopted has not been cited. [2] Another peak west of Overlord Mountain was identified as Red Mountain on a 1923 sketch by Canadian mountaineer Neal M. Carter. [28] [29] To avoid confusion, the name of that mountain was changed to Fissile Peak on September 2, 1930, for its fissility. [2] [28] In 1952, Canadian volcanologist William Henry Mathews identified Mount Price as Clinker Mountain in the American Journal of Science. [30] Clinker is a geological term used to describe rough lava fragments associated with 'a'a flows. The fragments are characterized by several sharp, jagged spines and are normally less than 150 millimetres (5.9 inches) wide. [31]

The name Mount Price appeared on a topographic map of Garibaldi Provincial Park in 1928. [32] It later appeared on National Topographic System maps 92G and 92J in 1930 after a committee of the Garibaldi Park Board was set up to deal with nomenclature. The committee requested that the Geographic Board of Canada adopt the name Mount Price for this mountain after Thomas E. Price, a former mountaineer and engineer of the Canadian Pacific Railway who was a member of the Garibaldi Park Board at the time of the park's formation in 1927. Price was born at Vancouver in 1887 and was a member of a mountaineering party that had climbed Mount Garibaldi by a new route in 1908. [2] Clinker Peak and Clinker Ridge were both officially named on September 12, 1972, to retain Mount Price's earlier name, Clinker Mountain. [33] [34]

Geological studies

The Clinker Peak lava flows were one of the first described occurrences of lava having been impounded by glacial ice. [35] They were the subject of significant study by William Henry Mathews, a pioneer in the study of subglacial eruptions and volcano-ice interactions in North America. In 1952, Mathews cited substantial evidence supporting the conclusion that the Clinker Peak lava flows ponded against glacial ice. This included the existence of glacially striated boulders in the lava flows, conformable relations with glacial till, abnormal structures indicative of extrusion into standing meltwater or against ice, and widespread breccia and pillows indicative of rapid quenching in meltwater or in water-soaked pyroclastic rocks under the ice. [30]

Accessibility

Daisy Lake Road, 30 kilometres (19 miles) north of Squamish, provides access to Garibaldi Provincial Park from Highway 99. [3] [36] At the end of this 2.5-kilometre-long (1.6-mile) road is the Rubble Creek parking lot from which the 9-kilometre-long (5.6-mile) Garibaldi Lake Trail extends to the Garibaldi Lake campground and ranger station. [3] [4] [36] [37] A 5-kilometre-long (3.1-mile) hiking trail, known as the Mount Price Trail or the Mount Price Route, commences past the ranger station. [4] [38] [37] This poorly marked path ascends to the shore of Garibaldi Lake and then returns inland where it traverses south along the lava flow forming The Barrier. The terrain of this part of the route is relatively rough, involving substantial scrambling over boulders of the lava flow. Eventually the trail reaches open terrain north of Mount Price and approaches the base of the volcano. Climbing Mount Price or Clinker Peak involves scree and snow plodding; both peaks do not require scrambling. [4]

See also

Notes

  1. The Holocene is the current geologic epoch, which began 11,700 years ago. [9]
  2. The Quaternary is the current geologic period, which began 2.58 million years ago. [9]
  3. Hornblende is a green to black amphibole mineral common in igneous and metamorphic rocks. [14]
  4. The Early Pleistocene is an unofficial sub-epoch that spans the Gelasian and Calabrian stages, which together cover a timespan ranging from 2.58 to 0.774 million years ago. [9] [15]
  5. The Middle Pleistocene is a synonymous term for the Chibanian stage, which spans the time between 774,000 and 129,000 years ago. [9] [17]
  6. Biotite is a dark green, black or brown mineral of the mica group. [18]

Related Research Articles

<span class="mw-page-title-main">Geology of the Lassen volcanic area</span> Geology of a U.S. national park in California

The Lassen volcanic area presents a geological record of sedimentation and volcanic activity in and around Lassen Volcanic National Park in Northern California, U.S. The park is located in the southernmost part of the Cascade Mountain Range in the Pacific Northwest region of the United States. Pacific Oceanic tectonic plates have plunged below the North American Plate in this part of North America for hundreds of millions of years. Heat and molten rock from these subducting plates has fed scores of volcanoes in California, Oregon, Washington and British Columbia over at least the past 30 million years, including these in the Lassen volcanic areas.

<span class="mw-page-title-main">Mount Mazama</span> Complex volcano in the Cascade Range

Mount Mazama is a complex volcano in the western U.S. state of Oregon, in a segment of the Cascade Volcanic Arc and Cascade Range. The volcano is in Klamath County, in the southern Cascades, 60 miles (97 km) north of the Oregon–California border. Its collapse, due to the eruption of magma emptying the underlying magma chamber, formed a caldera that holds Crater Lake. Mount Mazama originally had an elevation of 12,000 feet (3,700 m), but following its climactic eruption this was reduced to 8,157 feet (2,486 m). Crater Lake is 1,943 feet (592 m) deep, the deepest freshwater body in the U.S. and the second deepest in North America after Great Slave Lake in Canada.

<span class="mw-page-title-main">Mount Garibaldi</span> Stratovolcano in British Columbia, Canada

Mount Garibaldi is a dormant stratovolcano in the Garibaldi Ranges of the Pacific Ranges in southwestern British Columbia, Canada. It has a maximum elevation of 2,678 metres and rises above the surrounding landscape on the east side of the Cheakamus River in New Westminster Land District. In addition to the main peak, Mount Garibaldi has two named sub-peaks. Atwell Peak is a sharp, conical peak slightly higher than the more rounded peak of Dalton Dome. Both were volcanically active at different times throughout Mount Garibaldi's eruptive history. The northern and eastern flanks of Mount Garibaldi are obscured by the Garibaldi Névé, a large snowfield containing several radiating glaciers. Flowing from the steep western face of Mount Garibaldi is the Cheekye River, a tributary of the Cheakamus River. Opal Cone on the southeastern flank is a small volcanic cone from which a lengthy lava flow descends. The western face is a landslide feature that formed in a series of collapses between 12,800 and 11,500 years ago. These collapses resulted in the formation of a large debris flow deposit that fans out into the Squamish Valley.

<span class="mw-page-title-main">Garibaldi Volcanic Belt</span> Volcanic chain in southwestern British Columbia, Canada

The Garibaldi Volcanic Belt is a northwest–southeast trending volcanic chain in the Pacific Ranges of the Coast Mountains that extends from Watts Point in the south to the Ha-Iltzuk Icefield in the north. This chain of volcanoes is located in southwestern British Columbia, Canada. It forms the northernmost segment of the Cascade Volcanic Arc, which includes Mount St. Helens and Mount Baker. Most volcanoes of the Garibaldi chain are dormant stratovolcanoes and subglacial volcanoes that have been eroded by glacial ice. Less common volcanic landforms include cinder cones, volcanic plugs, lava domes and calderas. These diverse formations were created by different styles of volcanic activity, including Peléan and Plinian eruptions.

<span class="mw-page-title-main">Chilcotin Group</span> Large area of basaltic lava in south-central British Columbia, Canada

The Chilcotin Group, also called the Chilcotin Plateau Basalts, is a large area of basaltic lava that forms a volcanic plateau running parallel with the Garibaldi Volcanic Belt in south-central British Columbia, Canada.

<span class="mw-page-title-main">Hoodoo Mountain</span> Stratovolcano in British Columbia, Canada

Hoodoo Mountain, sometimes referred to as Hoodoo Volcano, is a potentially active stratovolcano in the Northern Interior of British Columbia, Canada. It is located 25 kilometres northeast of the Alaska–British Columbia border on the north side of the Iskut River opposite of the mouth of the Craig River. With a summit elevation of 1,850 metres and a topographic prominence of 900 metres, Hoodoo Mountain is one of many prominent peaks within the Boundary Ranges of the Coast Mountains. Its flat-topped summit is covered by an ice cap more than 100 metres thick and at least 3 kilometres in diameter. Two valley glaciers surrounding the northwestern and northeastern sides of the mountain have retreated significantly over the last hundred years. They both originate from a large icefield to the north and are the sources of two meltwater streams. These streams flow along the western and eastern sides of the volcano before draining into the Iskut River.

<span class="mw-page-title-main">Mount Meager massif</span> Group of volcanoes in British Columbia, Canada

The Mount Meager massif is a group of volcanic peaks in the Pacific Ranges of the Coast Mountains in southwestern British Columbia, Canada. Part of the Cascade Volcanic Arc of western North America, it is located 150 km (93 mi) north of Vancouver at the northern end of the Pemberton Valley and reaches a maximum elevation of 2,680 m (8,790 ft). The massif is capped by several eroded volcanic edifices, including lava domes, volcanic plugs and overlapping piles of lava flows; these form at least six major summits including Mount Meager which is the second highest of the massif.

<span class="mw-page-title-main">Mount Fee</span> Volcanic peak in the country of Canada

Mount Fee is a volcanic peak in the Pacific Ranges of the Coast Mountains in southwestern British Columbia, Canada. It is located 13 km (8.1 mi) south of Callaghan Lake and 21 km (13 mi) west of the resort town of Whistler. With a summit elevation of 2,162 m (7,093 ft) and a topographic prominence of 312 m (1,024 ft), it rises above the surrounding rugged landscape on an alpine mountain ridge. This mountain ridge represents the base of a north-south trending volcanic field which Mount Fee occupies.

<span class="mw-page-title-main">Garibaldi Lake volcanic field</span> Volcanic field in Canada

The Garibaldi Lake volcanic field is a volcanic field, located in British Columbia, Canada. It was formed by a group of nine small andesitic stratovolcanoes and basaltic andesite vents in the scenic Garibaldi Lake area immediately north of Mount Garibaldi during the late Pleistocene and early Holocene. The oldest stratovolcano, The Black Tusk, formed between about 1.3 and 1.1 million years ago (Ma). Following glacial dissection, renewed volcanism produced the lava dome and flow forming its summit. Other Pleistocene vents are located along and to the west of the Cheakamus River. Cinder Cone, to the east of The Black Tusk, produced a 9-km-long lava flow during the late Pleistocene or early Holocene.

<span class="mw-page-title-main">Spectrum Range</span> Mountain range in British Columbia, Canada

The Spectrum Range, formerly gazetted as the Spectrum Mountains and the Rainbow Mountains, is a small mountain range in Cassiar Land District of northwestern British Columbia, Canada. Located at the southern end of the Tahltan Highland, it borders the Skeena Mountains in the east and the Boundary Ranges of the Coast Mountains in the west. The Spectrum Range is surrounded by the Arctic Lake Plateau in the southwest and the Kitsu Plateau in the northwest, both of which contain volcanic features such as cinder cones. It lies at the southern end of the Mount Edziza volcanic complex which includes the two neighbouring plateaus as well as Mount Edziza and the Big Raven Plateau to the north. The mountain range is drained on all sides by streams within the Stikine River watershed and, unlike Mount Edziza to the north, contains relatively small separate glaciers. Mount Edziza Provincial Park is the main protected area surrounding the Spectrum Range.

<span class="mw-page-title-main">Cascade Volcanoes</span> Chain of stratovolcanoes in western North America

The Cascade Volcanoes are a number of volcanoes in a volcanic arc in western North America, extending from southwestern British Columbia through Washington and Oregon to Northern California, a distance of well over 700 miles (1,100 km). The arc formed due to subduction along the Cascadia subduction zone. Although taking its name from the Cascade Range, this term is a geologic grouping rather than a geographic one, and the Cascade Volcanoes extend north into the Coast Mountains, past the Fraser River which is the northward limit of the Cascade Range proper.

<span class="mw-page-title-main">Level Mountain</span> Volcanic complex in British Columbia, Canada

Level Mountain is a large volcanic complex in the Northern Interior of British Columbia, Canada. It is located 50 kilometres north-northwest of Telegraph Creek and 60 kilometres west of Dease Lake on the Nahlin Plateau. With a maximum elevation of 2,164 metres, it is the second-highest of four large complexes in an extensive north–south trending volcanic region. Much of the mountain is gently sloping; when measured from its base, Level Mountain is about 1,100 metres tall, slightly taller than its neighbour to the northwest, Heart Peaks. The lower, broader half of Level Mountain consists of a shield-like structure while its upper half has a more steep, jagged profile. Its broad summit is dominated by the Level Mountain Range, a small mountain range with prominent peaks cut by deep valleys. These valleys serve as a radial drainage for several small streams that flow from the mountain. Meszah Peak is the only named peak in the Level Mountain Range.

<span class="mw-page-title-main">Volcanism of Canada</span> Volcanic activity in Canada

Volcanic activity is a major part of the geology of Canada and is characterized by many types of volcanic landform, including lava flows, volcanic plateaus, lava domes, cinder cones, stratovolcanoes, shield volcanoes, submarine volcanoes, calderas, diatremes, and maars, along with less common volcanic forms such as tuyas and subglacial mounds.

<span class="mw-page-title-main">Geology of the Pacific Northwest</span>

The geology of the Pacific Northwest includes the composition, structure, physical properties and the processes that shape the Pacific Northwest region of North America. The region is part of the Ring of Fire: the subduction of the Pacific and Farallon Plates under the North American Plate is responsible for many of the area's scenic features as well as some of its hazards, such as volcanoes, earthquakes, and landslides.

<span class="mw-page-title-main">The Barrier</span> Lava dam in British Columbia, Canada

The Barrier is a lava dam retaining the Garibaldi Lake system in southwestern British Columbia, Canada. It is over 300 m (980 ft) thick and about 2.4 km (1.5 mi) long where it impounds the lake.

<span class="mw-page-title-main">Silverthrone Caldera</span> Caldera in British Columbia, Canada

The Silverthrone Caldera is a potentially active caldera complex in southwestern British Columbia, Canada, located over 350 kilometres (220 mi) northwest of the city of Vancouver and about 50 kilometres (31 mi) west of Mount Waddington in the Pacific Ranges of the Coast Mountains. The caldera is one of the largest of the few calderas in western Canada, measuring about 30 kilometres (19 mi) long (north-south) and 20 kilometres (12 mi) wide (east-west). Mount Silverthrone, an eroded lava dome on the caldera's northern flank that is 2,864 metres (9,396 ft) high, may be the highest volcano in Canada.

<span class="mw-page-title-main">The Volcano (British Columbia)</span> Mountain in British Columbia, Canada

The Volcano, also known as Lava Fork volcano, is a small cinder cone in the Boundary Ranges of the Coast Mountains in northwestern British Columbia, Canada. It is located approximately 60 km (40 mi) northwest of the small community of Stewart near the head of Lava Fork. With a summit elevation of 1,656 m (5,433 ft) and a topographic prominence of 311 m (1,020 ft), it rises above the surrounding rugged landscape on a remote mountain ridge that represents the northern flank of a glaciated U-shaped valley.

<span class="mw-page-title-main">Volcanic history of the Northern Cordilleran Volcanic Province</span> Geologic region in British Columbia and Yukon, Canada

The volcanic history of the Northern Cordilleran Volcanic Province presents a record of volcanic activity in northwestern British Columbia, central Yukon and the U.S. state of easternmost Alaska. The volcanic activity lies in the northern part of the Western Cordillera of the Pacific Northwest region of North America. Extensional cracking of the North American Plate in this part of North America has existed for millions of years. Continuation of this continental rifting has fed scores of volcanoes throughout the Northern Cordilleran Volcanic Province over at least the past 20 million years and occasionally continued into geologically recent times.

<span class="mw-page-title-main">Canadian Cascade Arc</span> Canadian segment of the North American Cascade Volcanic Arc

The Canadian Cascade Arc, also called the Canadian Cascades, is the Canadian segment of the North American Cascade Volcanic Arc. Located entirely within the Canadian province of British Columbia, it extends from the Cascade Mountains in the south to the Coast Mountains in the north. Specifically, the southern end of the Canadian Cascades begin at the Canada–United States border. However, the specific boundaries of the northern end are not precisely known and the geology in this part of the volcanic arc is poorly understood. It is widely accepted by geologists that the Canadian Cascade Arc extends through the Pacific Ranges of the Coast Mountains. However, others have expressed concern that the volcanic arc possibly extends further north into the Kitimat Ranges, another subdivision of the Coast Mountains, and even as far north as Haida Gwaii.

<span class="mw-page-title-main">Mount Cayley volcanic field</span> Remote volcanic zone in Canada

The Mount Cayley volcanic field (MCVF) is a remote volcanic zone on the South Coast of British Columbia, Canada, stretching 31 km (19 mi) from the Pemberton Icefield to the Squamish River. It forms a segment of the Garibaldi Volcanic Belt, the Canadian portion of the Cascade Volcanic Arc, which extends from Northern California to southwestern British Columbia. Most of the MCVF volcanoes were formed during periods of volcanism under sheets of glacial ice throughout the last glacial period. These subglacial eruptions formed steep, flat-topped volcanoes and subglacial lava domes, most of which have been entirely exposed by deglaciation. However, at least two volcanoes predate the last glacial period and both are highly eroded. The field gets its name from Mount Cayley, a volcanic peak located at the southern end of the Powder Mountain Icefield. This icefield covers much of the central portion of the volcanic field and is one of the several glacial fields in the Pacific Ranges of the Coast Mountains.

References

  1. 1 2 3 4 5 6 "Garibaldi Lake: Synonyms & Subfeatures". Global Volcanism Program . Smithsonian Institution. Archived from the original on July 22, 2021. Retrieved July 22, 2021.
  2. 1 2 3 4 5 6 7 8 "Mount Price". BC Geographical Names . Archived from the original on July 22, 2021. Retrieved January 30, 2024.
  3. 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 Wood, Charles A.; Kienle, Jürgen (1990). Volcanoes of North America: United States and Canada. Cambridge University Press. pp. 113–114, 143–144, 148. ISBN   0-521-43811-X. OCLC   1251392896.
  4. 1 2 3 4 5 Hui, Stephen (2018). "Hikes North of Vancouver". 105 Hikes In and Around Southwestern British Columbia. Greystone Books. ISBN   978-1771642873.
  5. 1 2 3 4 Hildreth, Wes (2007). Quaternary Magmatism in the Cascades Geologic Perspectives (PDF). United States Geological Survey. p. 67. ISBN   978-1411319455. Archived from the original (PDF) on March 26, 2009.
  6. 1 2 3 4 Russel, J. K.; Hickson, C. J.; Andrews, Graham (2007). "Canadian Cascade volcanism: Subglacial to explosive eruptions along the Sea to Sky Corridor, British Columbia". In Stelling, Pete; Tucker, David S. (eds.). Floods, Faults, and Fire: Geological Field Trips in Washington State and Southwest British Columbia. GSA Field Guides. Vol. 9. Geological Society of America. p. 12. doi:10.1130/2007.fld009(01). ISBN   978-0813700090.
  7. 1 2 3 4 Demarchi, Dennis A. (2011). An Introduction to the Ecoregions of British Columbia (PDF). Government of British Columbia. pp. 24, 25, 37, 38, 39, 47, 56, 113. Archived from the original (PDF) on May 11, 2021. Retrieved November 12, 2021.
  8. 1 2 3 "Garibaldi Provincial Park". BC Parks. Archived from the original on July 16, 2021. Retrieved January 30, 2024.
  9. 1 2 3 4 "International Chronostratigraphic Chart" (PDF). International Commission on Stratigraphy. March 2020. Archived (PDF) from the original on October 27, 2021. Retrieved January 30, 2024.
  10. Woodsworth, Glenn J. (April 2003). Geology and Geothermal Potantial of the AWA Claim Group, Squamish, British Columbia (PDF) (Report). Government of British Columbia. p. 10. Archived from the original (PDF) on January 9, 2022.
  11. "Garibaldi volcanic belt". Catalogue of Canadian volcanoes. Natural Resources Canada. April 2, 2009. Archived from the original on June 15, 2008. Retrieved January 21, 2011.
  12. Smellie, J. L.; Chapman, M. G. (2002). Volcano-Ice Interaction on Earth and Mars. Geological Society of London. p. 202. ISBN   978-1862391215. OCLC   879065355.
  13. Burwash, Edward M. (1914). "Pleistocene Vulcanism of the Coast Range of British Columbia". The Journal of Geology . 22 (3). University of Chicago Press: 262, 263. doi:10.1086/622148. S2CID   128978632.
  14. Bucksch, Herbert (2013). Dictionary Geotechnical Engineering / Wörterbuch GeoTechnik. Vol. 1. Springer Berlin Heidelberg. p. 308. ISBN   978-3662033265.
  15. Martin, C. J.; Griffiths, James S. (2017). Engineering Geology and Geomorphology of Glaciated and Periglaciated Terrains. Geological Society of London. p. 33. ISBN   978-1786203021.
  16. 1 2 3 4 5 Green, Nathan L. (1990). "Late Cenozoic Volcanism in the Mount Garibaldi and Garibaldi Lake Volcanic Fields, Garibaldi Volcanic Belt, Southwestern British Columbia". Geoscience Canada. 17 (3). Geological Association of Canada: 172, 173. ISSN   1911-4850.
  17. Tobratov, Sergei A.; Zheleznova, Olga S. (2020). "Experience of Large-Scale Analysis of the Spatial Patterns of Plain Forest Ecosystem Productivity and Biogeochemical Processes". In Frank-Kamenetskaya, Olga V.; Vlasov, Dmitry Yu.; Panova, Elena G.; Lessovaia, Sofia N. (eds.). Processes and Phenomena on the Boundary Between Biogenic and Abiogenic Nature. Springer Nature. p. 324. doi:10.1007/978-3-030-21614-6_18. ISBN   978-3030216139.
  18. West, Terry R.; Shakoor, Abdul (2018). "Minerals". Geology Applied to Engineering. Waveland Press. p. 25. ISBN   978-1478635000.
  19. 1 2 3 4 5 6 7 "Garibaldi volcanic belt: Garibaldi Lake volcanic field". Catalogue of Canadian volcanoes. Natural Resources Canada. April 1, 2009. Archived from the original on May 13, 2008. Retrieved January 21, 2011.
  20. 1 2 3 4 Evans, S.G.; Savigny, K.W. (1994). "Landslides in the Vancouver-Fraser Valley-Whistler region". Geology and Geological Hazards of the Vancouver Region, Southwestern British Columbia. Natural Resources Canada. pp. 268, 270. ISBN   978-0660157849. OCLC   32231242.
  21. "Where do landslides occur?". Government of British Columbia. Archived from the original on August 18, 2010. Retrieved January 21, 2012.
  22. Wilson, Alexander M.; Kelman, Melanie C. (2021). Assessing the relative threats from Canadian volcanoes (Report). Geological Survey of Canada, Open File 8790. Natural Resources Canada. p. 50. doi: 10.4095/328950 .
  23. "Volcanic hazards". Volcanoes of Canada. Natural Resources Canada. April 2, 2009. Archived from the original on February 2, 2009. Retrieved January 21, 2012.
  24. Neal, Christina A.; Casadevall, Thomas J.; Miller, Thomas P.; Hendley II, James W.; Stauffer, Peter H. (October 14, 2004). "Volcanic Ash–Danger to Aircraft in the North Pacific". United States Geological Survey. Archived from the original on July 18, 2021. Retrieved January 21, 2012.
  25. "Lava flows destroy everything in their path". United States Geological Survey. Archived from the original on July 5, 2021.
  26. "Monitoring volcanoes". Volcanoes of Canada. Natural Resources Canada. February 26, 2009. Archived from the original on June 8, 2008. Retrieved January 20, 2012.
  27. "Interagency Volcanic Event Notification Plan (IVENP)". Volcanoes of Canada. Natural Resources Canada. June 4, 2008. Archived from the original on February 14, 2009. Retrieved January 20, 2012.
  28. 1 2 "Fissile Peak". BC Geographical Names . Archived from the original on July 22, 2021. Retrieved January 30, 2024.
  29. Scott, Chic (2000). Pushing the Limits: The Story of Canadian Mountaineering . Rocky Mountain Books. p.  122. ISBN   978-0921102595. OCLC   45707893.
  30. 1 2 Mathews, W. H. (1952). "Ice-dammed lavas from Clinker Mountain, southwestern British Columbia". American Journal of Science . 250 (8). American Journal of Science: 553–565. Bibcode:1952AmJS..250..553M. doi:10.2475/AJS.250.8.553. S2CID   131690276.
  31. Bell, F. G. (1983). Fundamentals of Engineering Geology. Butterworth & Company. p. 17. ISBN   978-0408011693. OCLC   10243882.
  32. Campbell, A. J. (1928). Topographical Map of Garibaldi Park (Map). 1:40,000. British Columbia Department of Lands. Archived from the original on June 3, 2019. Retrieved April 16, 2022.
  33. "Clinker Peak". BC Geographical Names . Archived from the original on July 22, 2021. Retrieved January 30, 2024.
  34. "Clinker Ridge". BC Geographical Names . Archived from the original on July 22, 2021. Retrieved January 30, 2024.
  35. Wilson, A. M.; Russell, J. K. (2019). "Quaternary glaciovolcanism in the Canadian Cascade volcanic arc Paleoenvironmental implications". In Poland, Michael P.; Garcia, Michael O.; Camp, Victor E.; Grunder, Anita (eds.). Field Volcanology: A Tribute to the Distinguished Career of Don Swanson. GSA Special Papers. Vol. 538. Geological Society of America. p. 141. doi:10.1130/2018.2538(06). ISBN   978-0813795386. S2CID   214521258.
  36. 1 2 Eyton, Taryn (2021). "Garibaldi Lake and Taylor Meadows". Backpacking in Southwestern British Columbia: The Essential Guide to Overnight Hiking Trips. Greystone Books. ISBN   978-1771646697.
  37. 1 2 Anderson, Sean; Bryant, Leslie; Harris, Brian; Hoare, Jay; Hughes, Colin; Manyk, Mike; Mussio, Russell; Soroka, Stepan (2019). Vancouver, Coast & Mountains BC. Mussio Ventures. p. 135. ISBN   978-1926806952.
  38. "Hut Management Plan 2019" (PDF). University of British Columbia. 2019. Archived from the original (PDF) on August 4, 2021. Retrieved August 4, 2021.
This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.