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Tseax Cone (/ˈsæks/ SEE-aks) is a small volcano in the Nass Ranges of the Hazelton Mountains in northwestern British Columbia, Canada. It has an elevation of 609 metres (1,998 feet) and lies within an east–west valley through which a tributary of the Tseax River flows. The volcano consists of two nested structures and was the source of four lava flows that descended into neighbouring valleys. A secondary eruptive centre lies just north of Tseax Cone on the opposite side of a lava-dammed lake. It probably formed simultaneously with Tseax Cone but the timing of volcanism at the two centres is not precisely known; they were both active sometime in the last 800 years. The area has been designated as a provincial park to protect these features.

Tseax Cone
Aiyansh Volcano
Aerial view of a sparsely tree-covered, cone-shaped volcano with a crater on its summit surrounded by forest and a lake in the background.
Tseax Cone with Melita Lake in the background
Highest point
Elevation609 m (1,998 ft)[1]
Coordinates55°06′38″N 128°53′56″W / 55.11056°N 128.89889°W / 55.11056; -128.89889[2]
Naming
EtymologyTseax River (Ksi Sii Aks)[3]
Native nameWil Ksi Baxhl Mihl (Nisga'a)[4]
English translationWhere the Fire Ran Out[5]
Geography
Tseax Cone is located in British Columbia
Tseax Cone
Tseax Cone
Location in British Columbia
CountryCanada[6]
ProvinceBritish Columbia[6]
DistrictCassiar Land District[2]
Protected areaNisga'a Memorial Lava Bed Provincial Park[7]
Parent rangeNass Ranges[8]
Topo mapNTS 103P2 Lava Lake[2]
Geology
Rock ageLess than 800 years old[9]
Mountain typeTephra cones[6]
Rock type(s)Basanite and trachybasalt[6]
Volcanic regionNorthern Cordilleran Province[10]
Last eruption1690 ± 150 years[11]

Tseax Cone lies within an ecoregion characterized by mountainous terrain and several streams. Rainforests occur at the volcano as well as several species of mammals. Lichens and mosses cover most of the Tseax Cone lava flows, although rainforests and waterbodies also obscure them. The volcano is the subject of legends told by the local indigenous people. They describe the destruction of villages along the Nass River and the death of several people from inhaling fumes. Renewed eruptions at Tseax Cone could start wildfires and block local streams with lava flows. The volcano and lava flows can be accessed via provincial highways and backcountry roads.

Names and etymology

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Tseax Cone has been variously called Aiyansh Volcano, Aiyansh River Volcano, Tseax River Cone and Tseax Volcano.[12] Aiyansh comes from a Nisga'a word meaning "leafing early" or "early leaves" while Tseax comes from a Nisga'a word meaning "new water". Tseax is possibly a reference to the disturbed drainage patterns of the Tseax River caused by the volcanic eruption.[13] The well-established local name for the volcano, Tseax Cone, was adopted 13 December 1991 on the National Topographic System map 103P/2.[2] To the Nisga'a, Tseax Cone is known as Wil Ksi Baxhl Mihl; in their language it means "Where the Fire Ran Out" which is a reference to the volcanic eruption that sent lava spewing out of the volcano.[4][5]

Geography

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Location

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Tseax Cone is located about 60 kilometres (37 miles) north of Terrace near the Nisga'a villages of Gitwinksihlkw and Gitlaxt'aamiks.[4] It lies within a steep-sided, 5-kilometre-long (3.1-mile), east–west valley penetrating the Nass Ranges of the Hazelton Mountains.[8][14][15] Tseax Cone is situated at the outlet of Melita Lake, an expansion of Crater Creek which flows west into the Tseax River.[2][16][17] Crater Creek gets its name from being in association with Tseax Cone which is located on the eastern side of the creek.[2][17] The main cadastral survey subdivision at Tseax Cone is Cassiar Land District which lies north of 55th parallel north.[2][18]

Tseax Cone is situated within the Nass Mountains Ecosection, a biogeographic unit of the Nass Ranges Ecoregion characterized by mountains with jagged peaks, rounded summits and ridges. It is bounded on the west by the Kitimat Ranges and on the east by the Cranberry Upland and Nass Basin. Several streams flow through the Nass Mountains Ecosection, including the Wedeene River which is a tributary of the Kitimat River, the Zymoetz, Kitwanga and Kitsumkalum rivers which are tributaries of the Skeena River, and the Kiteen and Tseax rivers which are tributaries of the Nass River. Lakelse Lake, Kitsumkalum Lake and Lava Lake are among some of the lakes in this ecosection.[19]

The area has a climate that is somewhat transitional between those of coastal and continental regimes. It is wetter than other areas in the Nass Ranges Ecoregion due to air entering from the Pacific Ocean. Much of this Pacific air enters via the Skeena River valley or flows over the Kitimat Ranges, resulting in cloud cover and heavy rain. Short periods of extreme cold temperatures and deep snow occasionally occur as a result of cold Arctic air invading from the north.[19] Coastal Western Hemlock and subalpine Mountain Hemlock form rainforests in the area.[14][19] Areal wildlife includes marmots, goats, bears and moose.[20]

Lava flows

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Moss-covered lava in Nass Valley

Lichens and mosses cover large portions of a lava flow sequence originating from Tseax Cone. They range in colour from green to yellow and reach thicknesses of a few centimetres.[21] In the Tseax River valley, the lava flows have been almost completely covered by dense rainforest. They have also been partially obscured by streams and small lakes, including Vetter Creek, Ross Lake and the Tseax River, all of which are in the Tseax River valley.[22] Melita Lake and Lava Lake have ponded behind the lava flow sequence, although Lava Lake had already existed before the lava was issued; it merely increased in depth.[23]

Despite being covered by lichens, mosses, rainforests and bodies of water, the lava flow sequence is easily recognizable from aerial and satellite imagery, as well as field observations.[21] However, this may change by the end of the 21st century as lodgepole pine and cottonwood forests continue to develop on the lava flows in an increasingly wetter and milder climate. The growth of these forests is bolstered by the deposition of silt on the lava flows by local streams, providing soil for vegetation.[24]

Geology and geomorphology

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Background

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Tseax Cone is one of the southernmost volcanoes in the Northern Cordilleran Volcanic Province.[10] This is a broad area of shield volcanoes, lava domes, cinder cones and stratovolcanoes extending from northwestern British Columbia northwards through Yukon into easternmost Alaska. The dominant rocks comprising these volcanoes are alkali basalts and hawaiites, but nephelinite, basanite and peralkaline[a] phonolite, trachyte and comendite are locally abundant. These rocks were deposited by volcanic eruptions from 20 million years ago to as recently as a few hundred years ago. The cause of volcanic activity in the Northern Cordilleran Volcanic Province is thought to be due to rifting of the North American Cordillera driven by changes in relative plate motion between the North American and Pacific plates.[26]

Structure

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Tseax Cone has an elevation of 609 metres (1,998 feet) and consists of two nested structures: a smaller inner cone and a larger external spatter rampart.[1][27] The inner cone is 30–35 metres (98–115 feet) high and 290 metres (950 feet) in diameter, consisting mainly of black ejecta such as scoria, ballistics and lapilli.[7][27][28] It contains a 33-metre-deep (108-foot) volcanic crater with a diameter of 80 metres (260 feet). This cone was the source of an elongated tephra layer that extends 2.5 kilometres (1.6 miles) to the northeast, suggesting a northeasterly wind at the time of eruption.[27] The external spatter rampart, which has also been described as a cone, is about 15–25 metres (49–82 feet) high and 460 metres (1,510 feet) in diameter.[27][28] It consists of spatter and scoria that ranges in colour from reddish to brownish and black to grey.[28] The western and southern bases of the spatter rampart are buried by ejecta from the younger inner cone.[27] About 470 metres (1,540 feet) north of Tseax Cone and 150–200 metres (490–660 feet) north of Melita Lake is a much smaller, unnamed asymmetrical satellite cone. It is about 20 metres (66 feet) high, 50–55 metres (164–180 feet) in diameter and heavily oxidized, containing a 4-metre-deep (13-foot) and 7-metre-in diameter (23-foot) summit crater. Extending southwest of the satellite cone is an eruptive fissure consisting of three or four tephra mounds.[28][29] These mounds are a few metres high and are completely covered by black tephra. Red oxidized tephra beneath the black tephra was deposited by lava fountaining at the larger satellite cone.[28]

 
Tseax Cone from the southeast

Tseax Cone was the source of four distinct lava flows, all of which were probably erupted over a timespan of weeks to a few months.[4][27] The first flow is the longest and most voluminous, accounting for about 84% of the total volume of lava erupted from Tseax Cone. It travelled 31.6 kilometres (19.6 miles) through Crater Creek and Tseax River valleys to the Nass River where it forms a 3-kilometre-wide (1.9-mile) and 12-kilometre-long (7.5-mile) lava plain. The second flow, representing about 13% of the total volume of lava, travelled 21.6 kilometres (13.4 miles) through Crater Creek valley to near the mouth of the Tseax River valley. Both of these lava flows consist of pāhoehoe[b] and are poor in phenocrysts.[c] The third flow accounts for less than 2% of the total volume of lava. It travelled 7.2 kilometres (4.5 miles) through Crater Creek valley to near Ross Lake in the Tseax River valley. The fourth flow is the shortest and least voluminous of the four lava flows from Tseax Cone. It represents about 1% of the total lava volume and travelled Crater Creek for 5.3 kilometres (3.3 miles). These latter two lava flows consist of ʻaʻā[d] and are rich in phenocrysts.[23]

All of the lava flows from Tseax Cone contain intact and collapsed lava tubes.[29] At least four of these tubes are situated adjacent to and extend under Tseax Cone. They lie at an elevation of 590 metres (1,940 feet) and were the subject of a glaciological study in 1975. At the time of study, two of the four lava tubes were found to be ice-free most of the year. One of these tubes contained a small braided stream while the other tube was dry and did not contain any stream sediments. The lack of stream sediments in the latter lava tube indicated that it remained dry and did not contain permanent ice deposits. Floors of ice were blocking the other two slightly higher tubes. As much as 20 centimetres (7.9 inches) of water was covering the ice in summer, indicating that unlike the other two lava tubes, they did not have exit points for water runoff at their lowermost levels. There was no evidence that the ice was dissipating as in many other ice caves despite an approximate mean annual temperature of 5 degrees Celsius (41 degrees Fahrenheit). The petrographic characteristics of the ice deposits were found to be similar to those in alpine caves such as Eisriesenwelt Cave in Austria and Coulthard Cave in the Canadian Rockies.[31]

Tseax Cone and its eruptive products are basanitic and trachybasaltic in composition.[28] They cover about 36 square kilometres (14 square miles), have a total volume of around 0.5 cubic kilometres (0.12 cubic miles) and rest unconformably on glacial debris and sedimentary rocks of the Bowser Lake Group.[32] The Bowser Lake Group rocks are of Jurassic and Cretaceous age, consisting of grey sandstones and dark grey and black conglomerates, siltstones and mudstones. Some Eocene granites and granodiorites of the Coast Plutonic Complex are present adjacent to Tseax Cone.[14]

Age controversy

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The exact timing of volcanism at Tseax Cone has been a subject of controversy due to there being no direct written accounts.[33] Reports of the rich oral history of the local Nisga'a people by missionaries as early as the 1910s suggest that Tseax Cone was erupting around 1770.[34] However, the credibility of these reports has been disputed due to possible poor translation from Nisga'a to English. G. Hanson wrote in a 1923 Canada Department of Mines report that 170-year-old trees were found growing on lava from Tseax Cone; this would indicate an eruption prior to 1753. In 1935, Marius Barbeau concluded in the Canadian Geographical Journal that the latest eruption at Tseax Cone occurred in the late 18th century.[29] In 1977, G.P.V. Akrigg and H.B. Akrigg speculated in British Columbia Chronicle, 1847–1871: Gold & Colonists that the Tseax Cone eruption was witnessed by naval officer Juan Francisco de la Bodega y Quadra on 24 August 1775. However, this is extremely unlikely because Bodega y Quadra's schooner, the Sonora, was anchored more than 280 kilometres (170 miles) west of Tseax Cone across mountainous terrain.[35] Michael D. Higgins proposed in a 2008 Journal of Volcanology and Geothermal Research article that the 1700 Cascadia earthquake may have caused the latest Tseax Cone eruption by destabilizing a subterranean magmatic system.[36]

 
Tseax Cone lava flow in Nass Valley

Radiocarbon dating of trees killed by lava from Tseax Cone has also given inconclusive results. A lava-encased cottonwood near the Nass River was reported by Sutherland Brown in 1969 and Jack Souther in 1970 to have yielded a radiocarbon date of 220 ± 130 years. However, Lowdon et al. stated in a 1971 Radiocarbon article that this date was uncorrected and should in fact be 250 ± 130 years.[29] In 2001, M.C. Roberts and S. McCuaig reported in The Canadian Geographer that a wood fragment of a lava-encased tree yielded a radiocarbon date of 220 ± 130 years; they gave a corrected date of 230 ± 50 years.[37] The latter two radiocarbon dates were recalibrated by Michael D. Higgins in 2008 using calibration software and reinterpreted the age of the Tseax Cone eruption at between 1668 and 1714.[9][36] Charred wood beneath tephra about 890 metres (2,920 feet) northwest of Tseax Cone was reported by Williams-Jones et al. in 2020 to have yielded radiocarbon dates of 190 ± 15 years and 390 ± 15 years.[38]

It has been generally agreed by researchers that the Tseax Cone lava flows were emplaced during a single eruption.[23][39] However, whether the volcano itself is the product of one or more distinct eruptive episodes has been a point of conjecture.[39][40] In 1923, G. Hanson suggested that Tseax Cone formed during a single eruption. The single eruption hypothesis was also suggested by Sutherland Brown in 1969 but postulated that the volcano was destroyed by explosions and then reformed. In 1978, Vilho Wuorinen provided evidence for Tseax Cone having formed by two distinct eruptive episodes.[39] This included a difference in surface erosion between the external spatter rampart and the inner tephra cone, as well as a difference in vegetation cover between the two structures.[41] A charred tree trunk found standing in the vertical wall of the spatter rampart also yielded a radiocarbon date of 625 ± 70 years.[9] Based on this evidence, Wuorinen proposed that the spatter rampart was formed by an initial period of activity around 1325.[9][39] This eruptive period was followed by 375 years of dormancy, during which the spatter rampart was smoothed by erosion. A second eruptive episode around 1700 produced the inner tephra cone, the lava flows and the several smaller satellite cones in the area.[39] In 2020, Williams-Jones et al. reported new paleomagnetic and geochemical data supporting the hypothesis that the inner tephra cone, external spatter rampart, satellite cones, lava flows and tephra deposits were all formed during a single period of activity.[42]

Hazards and monitoring

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Nass Valley lava flow

The question of whether Tseax Cone formed during one or more distinct eruptive episodes has important implications for future activity and hazard mitigation efforts.[6] Renewed activity from Tseax Cone is unlikely if the volcano is monogenetic. This is because monogenetic volcanoes are typically considered to erupt only once and to be short-lived.[43] If Tseax Cone is polygenetic, future activity could produce lava flows and potentially block local streams as happened previously. Damming of the Nass River by lava flows could negatively affect the salmon fisheries on that river. Carbon dioxide emissions from Tseax Cone could pose a threat to local inhabitants due to the gas's ability to replace oxygen in low-lying areas and poorly ventilated structures. Another potential hazard relating to future activity from Tseax Cone is the ignition of wildfires by eruptions as the area contains vegetation.[7]

Like other volcanoes in Canada, Tseax Cone 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 volcano. It may sense an increase in seismic activity if Tseax Cone 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.[44] If Tseax Cone 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.[45]

Human history

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Indigenous peoples

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Detail of lava flow in Nass Valley

Tseax Cone is a prominent figure in Nisga'a history and culture due to its association with a natural disaster.[35] According to Nisga'a legends, the Tseax Cone eruption caused the deaths of 2,000 people and the destruction of at least three villages on the banks of the Nass River.[6][7] This would make it the deadliest geological disaster in Canada and the second-worst natural disaster in Canadian history by death toll, succeeded only by the 1775 Newfoundland hurricane which caused at least 4,100 fatalities.[6][46] The three Nisga'a villages destroyed by the eruption have been named Lax Ksiluux, Lax Ksiwihlgest and Wii Lax K'abit.[6][47] Early 19th century Nisga'a accounts of the Tseax Cone eruption were reported by anthropologist Marius Barbeau in 1935 as follows:

...the volcanic eruption soon after broke out. First there was smoke, like that coming out of a house, a big pillar of smoke. It was as if a house was burning on the mountain top. The people saw a big fire. The fire came down the side in their direction, but not as fast as forest fire. It moved down slowly, very slowly. It was strange and frightful. It was dangerous! There were fumes spreading ahead, and those who smelled them were smothered. They died and their body stiffened like rock. Frightened, the people of one tribe dug holes in the ground like underground lodges, and hid within, scared as they were of the mountain spirits. Likewise, the other tribe. That did not keep other people from dying of the fumes, mostly in the lower of the villages. As soon as the smoke dispersed some people ran away; a great many others stayed on. They did not suffer any more from the smoke. The fire then rolled down like a river, filled the lake, and for a time the water was a bed of flames. The stone was red and hot there for many days. As far as it went, all the way, it was flowing red. It started from the river where the people fished salmon, away up there, and ran down to the place where the canyon now is...[35]

The "poisonous smoke" mentioned in Barbeau's report may have been odourless carbon dioxide.[7] It has been hypothesized that the Nisga'a casualties resulted from a carbon dioxide gravity current released by the sudden overturning of a former marshy lake adjacent to the destroyed Nass Valley villages. This overturning may have been caused by earthquakes accompanying the Tseax Cone eruption or by the sudden heating of lake waters when lava entered the Nass River.[48] Another hypothesis proposed by researchers is that while some of the Nisga'a attempted to escape the eruption by canoe on the Nass River, they were killed by boiling river water or were swept away in a flood as lava displaced the river.[48][49] Some of the Nisga'a deaths may have also resulted from wildfires ignited by the lava.[48]

The Nisga'a also recall the disruption of the Tseax River, stating that "before the volcanic eruption, when our people lived here at Wii Lax K'ap, there was a stream close by where salmon spawned. The stream bed had white sand and they could easily spot the salmon going up stream. This stream was thus named Ksi Gimwits'ax. Years later [after the volcanic eruption] when this stream resurfaced, and though the Nisga'a knew it was the same tributary, it was renamed Ksi Sii Aks."[3] A salamander species that once inhabited the bay area of Gitwinksihlkw on the Nass River is said to have disappeared or became extinct following the Tseax Cone eruption.[47]

Protection

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Tseax Cone and its eruptive products are protected in Nisga'a Memorial Lava Bed Provincial Park.[7] This 17,717-hectare (43,780-acre) protected area was founded in 1992 to preserve the volcanic landscape and to honour the 2,000 Nisga'a people who died during the Tseax Cone eruption.[7][20] It was the first provincial park in British Columbia to be managed by both BC Parks and a First Nation, as well as the first provincial park in British Columbia to combine indigenous culture and natural features.[20] The former Nisga'a Memorial Lava Bed Recreation Area was annexed into Nisga'a Memorial Lava Bed Provincial Park in 1995.[50]

Accessibility

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The Tseax Cone lava flows are most easily accessed by travelling the Nisga'a Highway north of Terrace for 100 kilometres (62 miles), the final 30 kilometres (19 miles) of which is unpaved. An alternative route to the lava flows involves travelling the paved Stewart–Cassiar Highway north of Kitwanga for 78 kilometres (48 miles) to the Cranberry River.[20] From there, the unpaved Nass Forest Service Road extends 86 kilometres (53 miles) southwest to Gitlaxt'aamiks which lies on the northeastern edge of the lava flows.[12][20] Access to Tseax Cone is limited only to a 6-kilometre-long (3.7-mile) guided hiking tour from an access road 1.4 kilometres (0.87 miles) north of the Lava Lake picnic site on the Nisga'a Highway.[20]

See also

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Notes

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  1. ^ Peralkaline rocks are magmatic rocks that have a higher ratio of sodium and potassium to aluminum.[25]
  2. ^ Pāhoehoe is basaltic lava with a smooth, glassy, undulating and porous surface.[25]
  3. ^ Phenocrysts are large, conspicuous crystals in magmatic rocks with porphyritic texture.[25]
  4. ^ ʻAʻā is lava with a rough rubbly surface composed of broken blocks called clinkers.[30]

References

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  1. ^ a b "Tseax River Cone: General Information". Global Volcanism Program. Smithsonian Institution. Archived from the original on 2021-10-29. Retrieved 2021-11-17.
  2. ^ a b c d e f g "Tseax Cone". BC Geographical Names. Retrieved 2021-11-17.
  3. ^ a b "Ksi Sii Aks". BC Geographical Names. Archived from the original on 2021-11-27. Retrieved 2022-03-29.
  4. ^ a b c d Le Moigne et al. 2020, p. 363.
  5. ^ a b "Lava beds and other reasons to love northern British Columbia". Postmedia Network. 2019-11-06. Archived from the original on 2021-04-21. Retrieved 2022-01-12.
  6. ^ a b c d e f g h Williams-Jones et al. 2020, p. 1238.
  7. ^ a b c d e f g "Tseax Cone". Catalogue of Canadian volcanoes. Natural Resources Canada. 2005-08-19. Archived from the original on 2008-01-11. Retrieved 2022-01-12.
  8. ^ a b "Tseax Cone". Geographical Names Data Base. Natural Resources Canada. Retrieved 2023-10-06.
  9. ^ a b c d Williams-Jones et al. 2020, p. 1242.
  10. ^ a b Slaymaker, Olav (2017). Landscapes and Landforms of Western Canada. Springer International Publishing. p. 52. ISBN 978-3-319-44593-9.
  11. ^ "Tseax River Cone: Eruptive History". Global Volcanism Program. Smithsonian Institution. Archived from the original on 2021-10-29. Retrieved 2021-11-17.
  12. ^ a b Williams-Jones et al. 2020, p. 1239.
  13. ^ Akrigg, G.P.V.; Akrigg, Helen B. (1997). British Columbia Place Names (3rd ed.). University of British Columbia Press. pp. 3, 273. ISBN 0-7748-0636-2.
  14. ^ a b c Le Moigne et al. 2020, p. 364.
  15. ^ Denton, George H. (1975). "Glaciers of the Interior Ranges of British Columbia". Mountain Glaciers of the Northern Hemisphere (Report). Vol. 1. American Geophysical Society. p. 662. Retrieved 2023-10-07.
  16. ^ "Melita Lake". BC Geographical Names. Archived from the original on 2021-11-26. Retrieved 2023-10-07.
  17. ^ a b "Crater Creek". BC Geographical Names. Archived from the original on 2021-11-26. Retrieved 2023-10-07.
  18. ^ "Cassiar Land District". BC Geographical Names. Archived from the original on 2018-06-27. Retrieved 2023-10-07.
  19. ^ a b c Demarchi, Dennis A. (2011). An Introduction to the Ecoregions of British Columbia. Government of British Columbia. pp. 36, 37. OCLC 613357103.
  20. ^ a b c d e f "Anhluut'ukwsim Lax̱mihl Angwinga'asanakwhl Nisga'a [a.k.a. Nisga'a Memorial Lava Bed Park]". BC Parks. Archived from the original on 2024-01-18. Retrieved 2023-10-24.
  21. ^ a b Le Moigne et al. 2020, pp. 365, 367.
  22. ^ Le Moigne et al. 2020, p. 367.
  23. ^ a b c Le Moigne et al. 2020, p. 369.
  24. ^ "Researchers Investigate how Vegetation is Changing at Nisga'a Memorial Lava Bed Park". Government of British Columbia. 2019-11-14. Archived from the original on 2023-06-08. Retrieved 2023-10-23.
  25. ^ a b c Imam, Naiyar (2003). Dictionary of Geology and Mineralogy. McGraw–Hill Companies. pp. 238, 253, 257. ISBN 0-07-141044-9.
  26. ^ Edwards, Benjamin R.; Russell, James K. (2000). "Distribution, nature, and origin of Neogene–Quaternary magmatism in the northern Cordilleran volcanic province, Canada". Geological Society of America Bulletin. 112 (8). Geological Society of America: 1280, 1281. Bibcode:2000GSAB..112.1280E. doi:10.1130/0016-7606(2000)112<1280:dnaoon>2.0.co;2. ISSN 0016-7606.
  27. ^ a b c d e f Le Moigne, Yannick; Williams-Jones, Glyn; Vigouroux, Nathalie; Kelly Russell, James (2022). "Chronology and Eruption Dynamics of the Historic∼1700 CE Eruption of Tseax Volcano, British Columbia, Canada". Frontiers in Earth Science. 10. Frontiers Media: 1, 7. Bibcode:2022FrEaS..10.0451L. doi:10.3389/feart.2022.910451. ISSN 2296-6463.
  28. ^ a b c d e f Le Moigne et al. 2020, p. 365.
  29. ^ a b c d Williams-Jones et al. 2020, p. 1241.
  30. ^ "USGS Volcano Hazards Program Glossary". United States Geological Survey. 2018. Archived from the original on 2023-11-27. Retrieved 2023-12-22.
  31. ^ Marshall, Peter (1975). "Ice-Blocked Tubes in the Aiyansh Flow, British Columbia". Arctic and Alpine Research. 7 (4). Institute of Arctic and Alpine Research: 399, 400. doi:10.1080/00040851.1975.12003851.
  32. ^ Le Moigne et al. 2020, pp. 364, 368.
  33. ^ Williams-Jones et al. 2020, pp. 1241, 1250.
  34. ^ Williams-Jones et al. 2020, pp. 1238, 1241.
  35. ^ a b c Williams-Jones et al. 2020, p. 1250.
  36. ^ a b Higgins, Michael D. (2009). "The Cascadia megathrust earthquake of 1700 may have rejuvenated an isolated basalt volcano in western Canada: Age and petrographic evidence". Journal of Volcanology and Geothermal Research. 179 (1). Elsevier: 149, 150, 151. Bibcode:2009JVGR..179..149H. doi:10.1016/j.jvolgeores.2008.10.016. ISSN 0377-0273.
  37. ^ Williams-Jones et al. 2020, pp. 1241, 1242.
  38. ^ Williams-Jones et al. 2020, pp. 1239, 1242.
  39. ^ a b c d e Wuorinen, Vilho (1978). "Age of Aiyansh Volcano, British Columbia". Canadian Journal of Earth Sciences. 15 (6). NRC Research Press: 1037, 1038. Bibcode:1978CaJES..15.1037W. doi:10.1139/e78-111.
  40. ^ Williams-Jones et al. 2020, p. 1248.
  41. ^ Williams-Jones et al. 2020, pp. 1242, 1243.
  42. ^ Williams-Jones et al. 2020, pp. 1238, 1247.
  43. ^ Vargas-Arcila, Laura; Murcia, Hugo; Osorio-Ocampo, Susana; Sánchez-Torres, Laura; Botero-Gómez, Luis Alvaro; Bolaños, Gina (2023). "Effusive and evolved monogenetic volcanoes: two newly identified (~800 ka) cases near Manizales City, Colombia". Bulletin of Volcanology. 85 (42). Springer Science+Business Media: 41. Bibcode:2023BVol...85...42V. doi:10.1007/s00445-023-01655-y. ISSN 0258-8900. S2CID 259277907.
  44. ^ "Monitoring volcanoes". Volcanoes of Canada. Natural Resources Canada. 2009-02-26. Archived from the original on June 8, 2008. Retrieved 2022-04-09.
  45. ^ "Interagency Volcanic Event Notification Plan (IVENP)". Volcanoes of Canada. Natural Resources Canada. 2008-06-04. Archived from the original on February 14, 2009. Retrieved 2022-04-09.
  46. ^ "Volcano Watch — Volcanoes in Canada, eh?". United States Geological Survey. 2021-07-01. Archived from the original on 2022-11-03. Retrieved 2023-10-22.
  47. ^ a b "Gitwinksihlkw". BC Geographical Names. Archived from the original on 2020-02-18. Retrieved 2023-11-30.
  48. ^ a b c Gallo, Rose (2018). History and Dynamics of Explosive Volcanism at Tseax Cone, British Columbia (BSc thesis). University of British Columbia. p. 5. Retrieved 2023-10-21.
  49. ^ Hickson, C.J.; Spurgeon, T.C.; Cocking, R.B.; Russel, J.K.; Woodsworth, G.J.; Ulmi, M.; Rust, A.C. (2007). "Tseax Volcano: A Deadly Basaltic Eruption in North-Western British Columbia, Canada". Geological Society of America. Archived from the original on 2023-06-04. Retrieved 2023-10-24.
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