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Líĺwat Climbers Could See the Ocean from the Peak of Qẃelqẃelústen: Evaluating Oral Traditions with Viewshed Analyses from the Mount Meager Volcanic Complex Prior to Its 2360 BP Eruption

Published online by Cambridge University Press:  23 May 2024

Bill Angelbeck*
Affiliation:
Department of Anthropology and Sociology, Douglas College, New Westminster, BC, Canada
Chris Springer
Affiliation:
Independent Researcher, Maple Ridge, BC, Canada
Johnny Jones
Affiliation:
Land & Resources Department (retired), Líĺwat Nation, Mount Currie, BC, Canada
Glyn Williams-Jones
Affiliation:
Centre for Natural Hazards Research, Department of Earth Sciences, Simon Fraser University, Burnaby, BC, Canada
Michael C. Wilson
Affiliation:
Department of Earth and Environmental Sciences (emeritus), Douglas College, New Westminster, BC, Canada
*
Corresponding author: Bill Angelbeck; Email: [email protected]
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Abstract

Among Líĺwat people of the Interior Plateau of British Columbia, an oral tradition relays how early ancestors used to ascend Qẃelqẃelústen, or Mount Meager. The account maintains that those climbers could see the ocean, which is not the case today, because the mountain is surrounded by many other high peaks, and the Strait of Georgia is several mountain ridges to the west. However, the mountain is an active and volatile volcano, which last erupted circa 2360 cal BP. It is also the site of the largest landslide in Canadian history, which occurred in 2010. Given that it had been a high, glacier-capped mountain throughout the Holocene, much like other volcanoes along the coastal range, we surmise that a climber may have reasonably been afforded a view of the ocean from its prior heights. We conducted viewshed analyses of the potential mountain height prior to its eruption and determined that one could indeed view the ocean if the mountain were at least 950 m higher than it is today. This aligns with the oral tradition, indicating that it may be over 2,400 years old, and plausibly in the range of 4,000 to 9,000 years old when the mountain may have been at such a height.

Resumen

Resumen

Entre el pueblo Lil'wat de la meseta interior de la provincia de British Columbia, una tradición oral relata cómo los primeros ancestros solían ascender al Qẃelqẃelústen / Monte Meager. La narración sostiene que los escaladores podían ver el océano, evento que no sucede más actualmente, ya que la montaña está rodeada de muchos picos altos y el estrecho de Georgia está formado por varias crestas montañosas al Oeste. Sin embargo, el Monte Meager es un volcán activo que erupcionó por última vez hace aproximadamente 2360 años antes del presente y también es el sitio donde sucedió el deslizamiento de tierra más grande en la historia de Canadá en 2010. Considerando que durante todo el Holoceno este volcán fue más alto y cubierto de glaciar, parecido a otros volcanes localizados a lo largo de la cordillera costera, suponemos que un escalador podía razonablemente acceder a la vista del océano debido a la altitud del volcán en aquel tiempo. Conducimos un análisis de visibilidad de la altura potencial de la montaña antes de su erupción, y determinamos que efectivamente se podía ver el océano si el monte era al menos 950 metros más alto de lo que es hoy. Esto coincide con la tradición oral, lo que indica que el volcán podría haber tenido esa altura hace más de 2,400 años, y posiblemente entre 4.000 y 9.000 años antes del presente.

Type
Article
Copyright
Copyright © The Author(s), 2024. Published by Cambridge University Press on behalf of Society for American Archaeology

That's where they stood on top of the mountain and they could see the ocean. That was before it blew its top. . . . That was the highest mountain at one time.

— Harry Dick (Reference Dick, Angelbeck, Sanders and Hall2011)

An oral history among the Líĺwat people of the Interior Plateau of British Columbia recounts how ancient climbers used to ascend Qẃelqẃelústen, once regarded as the highest mountain in their traditional territory. It was so high, their legends recounted, that one could see the ocean. This is not the case today, because the peak is surrounded by other high prominences of similar heights, and the Strait of Georgia is beyond several montane ridges to the west. However, Qẃelqẃelústen, also known as the Mount Meager Volcanic Complex, is characterized by long-lived volcanic activity having developed over a period of about 2 mya, with its last explosive eruption circa 2,360 years ago (e.g., Harris et al. Reference Harris, Russell, Muhammad and Williams-Jones2022; Read Reference Read1990). The glacier-clad massif is currently made up of numerous individually named volcanic peaks and notable for its long record of landslides due to the combination of extensive hydrothermal alteration and glacial erosion (e.g., Friele et al. Reference Friele, Jakob and Clague2008; Roberti et al. Reference Roberti, Ward, van Wyk de Vries, Falorni, Menounos, Friele and Williams-Jones2018; Figures 1 and 2).

Figure 1. Location of Qẃelqẃelústen / Mount Meager massif in south-central British Columbia.

Figure 2. Topographic map indicating current peaks of the Mount Meager Complex.

Given that the mountain may plausibly have been much higher prior to the 2360 cal BP eruption, we surmise that its previous height may have allowed one to see the ocean. Consequently, it is possible that the Líĺwat oral tradition is based on such geological knowledge of its history and encodes it within its oral narratives. Here, we present the results of viewshed analyses of the potential mountain height prior to its eruption collapse. The results indicate that one could indeed see the ocean if the mountain was at least 950 m higher. These results provide support for observations recorded in the oral tradition and suggest that the oral tradition may be well over 2,400 years old.

In the following article, we present Líĺwat oral traditional knowledge about Qẃelqẃelústen, its surroundings, and associated sites as recounted through various narratives and cultural knowledge, including place-names. In addition, we discuss how Indigenous traditions more generally provide intimate knowledge of volcanoes and high montane landscapes extending back millennia in the Pacific Northwest, and how they often form a core part of their territorial identity. We also present the volcanic geological history of the Mount Meager Volcanic Complex and discuss the possibility for its higher peaks in the millennia prior to the last eruption. Next, we detail the viewshed analyses conducted at various heights in the center of the complex to show that the ocean could be viewed from its previous heights. We discuss our results in light of other studies that have provided evidential support for oral traditions, providing another instance in which the great antiquity of Indigenous oral traditions can be maintained over millennia.

Oral Traditions about Líĺwat Climbers

Harry Dick, an elder among the Líĺwat Nation, has a story about early ancestors who climbed Qẃelqẃelústen (Mount Meager) long ago.Footnote 1 Two of the authors here, Bill Angelbeck and Johnny Jones / Yaqalatqa7, recorded an interview with him about the upper reaches of Líĺwat traditional territory. Indeed, when asked about Qẃelqẃelústen, he recounted the following:

One thing about Meager, I knew, is . . . when they first founded Lillooet territory is there's three . . . what did they call them [in English]? [Founders or transformers]—but anyhow, that's where they stood on top of the mountain and they could see the ocean. That was before it blew its top. . . . It was a dangerous place to be. . . . That was the highest mountain at one time—our grandmother told us. . . . The people that founded the Líĺwat territory, that's where they met, then they came down [Dick Reference Dick, Angelbeck, Sanders and Hall2011:261].

In this account, we should first point out that Dick notes that this knowledge is associated with the earliest times of occupation and founding of the Líĺwat territory.

Furthermore, it is associated with the Time of Transformation, when Transformer figures traversed Líĺwat territory, altering the landscape into its general contemporary shape and converting many individuals or animals into distinctive geological features throughout the region. This was the general time of the Copper Canoe brothers, who were Líĺwat shamans seeking spirit powers at the base of Qẃelqẃelústen. The narratives of their adventures detail how they shaped much of the Upper Lillooet River valley. Consequently, the story is viewed as ancient, one that is associated with the earliest Transformers and ancestors of Líĺwat territory. Second, Dick (Reference Dick, Angelbeck, Sanders and Hall2011) acknowledges that it is impossible to see the ocean today but maintains that the narrative describes how the mountain had been much higher than it is now, that it was the “highest mountain at one time.” Third, he also recounts some of the lineage of its telling. His grandmother provided the account, and he is a contemporary bearer of this story. He has also stated that he heard this story from grandparents on both sides of his family; his grandmother had recounted to him in their original language of Ucwalmícwts. In addition, other Líĺwat members also had heard the story (Angelbeck and Yard Reference Angelbeck and Yard2022:51).

This, however, is not the only account about the mountain and how it figures prominently in Líĺwat oral traditions. A recounting of some of these traditions provides context for this oral narrative.

Oral Traditions of the Qẃelqẃelústen Area

Charlie Mack, a renowned storyteller of the Líĺwat, recounted that Qẃelqẃelústen was an important place for Líĺwat people. Further, Qẃelqẃelústen was always regarded as a powerful and dangerous locale. As Kennedy and Bouchard (Reference Kennedy and Bouchard2010:18) relayed, Mack maintained there were tales of: “Líĺwat adventurers, men far more spiritually powerful than himself, who also faced the mountain. Some call the mountain’s power supernatural, mysterious, or even sacred.”

Mack referred to it, in the Líĺwat language of Ucwalmícwts, as hi7—a term that has “spiritually powerful” qualities, considered both sacred and dangerous. For him, this mountain was “kinda ‘monster’” (as quoted in Kennedy and Bouchard Reference Kennedy and Bouchard2010:19). In one story, an old man named 25-Mile Jim and a scwená7em, or shaman, attempted to climb the mountain, and the wind gusts around the top of the mountain were too strong:

Well, they [were] blowed away. . . . They just walked off, they can't do nothing. They were hunting, they go up there to hunt goats and they couldn't make it. Then they start to make a noise; I guess they echo to the high mountain, and it start to blow. Well, 25-Mile Jim, he says: “I seen rocks go up in the air.” It was blowing so hard, on the other end of the rock. It seems the echo started the hi7 [Mack in Kennedy and Bouchard Reference Kennedy and Bouchard2010:19].Footnote 2

The name of the mountain, Qẃelqẃelústen, means “cooked face place” or “cooked fire place”: qẃel means “done, ripe, or cooked” and qẃelqẃel is a repetition, meaning that it is “very cooked”; the suffix -us is used for “face,” “hill,” or “fire,” and the other suffix -ten indicates a location or place (also instrument or thing; Abraham Reference Abraham2000:1). Charlie Mack has described Qẃelqẃelústen as “the place where goat heads are cooked,” which connects the traditional practice of hunting mountain goats with the associations of the heat of the place (quoted in Bouchard et al. Reference Bouchard, Mack and Ritchie1975). Even today, the mountain emits clouds of volcanic gas from fumaroles within glaciovolcanic caves on Job Glacier (e.g., Warwick et al. Reference Warwick, Williams-Jones, Kelman and Witter2022). Furthermore, evidence of the extensive volcanic hydrothermal system is provided by at least two hot springs, or tsek, at the mountain's base, near the confluences of two creeks that flow at its base: Pebble Creek, which flows to its southeast, and Nqempa stswaw'cw / Meager Creek, flowing to its southwest (Figure 2). Heat, cooking, and hot springs—all of these connotations are long held in Líĺwat oral traditions about this mountain.

Other important narratives are connected with Qẃelqẃelústen, including a story from the Time of Transformation. Two shaman brothers, or scwená7em, sought to train for spiritual powers at the base of the mountain, because it was hi7. It is also remote—a location that is well north of Líĺwat villages, close to the headwaters of the main river, Líĺwatátkwa/Lillooet River, from which they share their own name as Líĺwat. This sharing of name indicates how tied the Líĺwat are to this important river throughout their history. In Charlie Mack's telling, the brothers camped near the confluence of Salal Creek, at the base of the east slope of Qẃelqẃelústen (Kennedy and Bouchard Reference Kennedy and Bouchard2010:20–21). James Teit (Reference Teit1912:303–304) is less specific, but he does note that it is at the headwaters of Líĺwatátkwa: “Two brothers lived at the very head waters of the Upper Lillooet River, and spent most of their time training themselves in the neighbouring mountains for they wished to become great.”

The headwaters of the river encompass Mount Meager, the Lillooet Glacier, and Salal Creek, among other tributaries of the Upper Lillooet River within its viewshed. One of the brothers has a vision of a copper canoe:

And they were bathing in there, singing at night, dreaming. They said they were scared sometimes when they dream something bad. If they are big enough, they grab a hold of it, what they dream. That is how they got this canoe. . . . They went to sleep and dream[t] about a canoe. A canoe, a Copper Canoe, and he grab a hold of it. When he got it, well, he own it; the canoe didn’t disappear. . . . It started above the canyon, above the waterfall [Charlie Mack, quoted in Kennedy and Bouchard Reference Kennedy and Bouchard2010:20–21].

Therefore, one of the scwená7em grabbed hold of this copper canoe from the dreamworld of his vision and pulled it into reality, and the two brothers hopped in it and floated down Líĺwatátkwa/Upper Lillooet River, facing numerous obstructions along the way, routing its new course altering the landscape in the process. The first obstacle to the brothers in the canoe was a wall of stone at the base of Qẃelqẃelústen, which Teit (Reference Teit1912:303) named Ilamüx: “They came to a place called Ilamüx. Here there was a rock which dammed the river. They made a hole through it to allow their canoe to pass. Even at the present day it appears like a stone bridge across the river.”

With their copper canoe, they sliced through the rock wall—“cut right through there,” says Mack—forming a slit from which the water descended into whirling pools at the base. The waterfall is named Múmleq. The shape of the narrow cut has resulted in it being called Keyhole Falls today. The brothers continued their journey south of Qẃelqẃelústen, encountering other obstacles, such as shifting mountains blocking their path, high gravel beds, and knots of bulrushes. With the copper canoe, they were able to overcome them as they continued their journey all the way down the course of the Lillooet River to its confluence with the Fraser River, and ultimately, to its mouth at the Salish Sea. At that point, they reached the “land of the salmon.”

However, the salmon were blocked by a massive fish weir.Footnote 3 They ingratiated themselves with those that maintained the weir, however, and eventually pulled up some weir stakes, creating a gap that allowed the salmon to proceed upriver. One of the brothers “hollered up the river, ‘Fix up the smokehouse, the fish [are] coming up now’” (Kennedy and Bouchard Reference Kennedy and Bouchard2010:27). In so doing, the two scwená7em brothers, who gained their powers at the base of Qẃelqẃelústen, introduced salmon into Líĺwat territory—one of their staple resources.

The two brothers followed the salmon up the river all the way back to Qẃelqẃelústen, where they took the salmon and cooked it in the waters of one of the hot springs. In a way, they complete the cycle and return to the starting point, symbolically emphasizing the connection of the powers of Qẃelqẃelústen to salmon. Elder Louie Joe (Reference Joe, Angelbeck, Sanders and Hall2011) also recounted memories of how such practices continue among Líĺwat—given that his father used to travel up to Meager Hot Springs, always staying for several days, using the heated mineral waters to help train himself spiritually—and that Charlie Mack had cooked fish in the hot springs.

The whole region surrounding Qẃelqẃelústen contains places that are important to the Líĺwat. The mountain is a place of spiritual reverence for them, owing to its spiritual, or áx7a, powers related to the Copper Canoe brothers long ago. The presence of two hot springs at the lower flanks of the mountain attest to locales sought for spiritual bathing, like the ones the original Copper Canoe brothers had sought. The mountain is more than a spiritual place, however, because it is a primary hunting locale, in particular for mountain goat. The southwestern flank of the mountain is called Ts’áq’alts, which translates as “peace-pipe rocks,” possibly indicating its shape or indicating a lithic resource area (Abraham Reference Abraham2000:2). It is associated with numerous other resource-gathering activities, such as Indian paint fungus, cedar bark, and various mushrooms particular to the volcanic environments (Angelbeck and Yard Reference Angelbeck and Yard2022).

Throughout his life, Charlie Mack would camp at the mountain with family and friends for two weeks each year, going by canoe upriver as far as they could and then hiking the rest of the way. The men hunted, and women gathered yellow avalanche lily and dogtooth violet roots, or “wild sweet potatoes” (Kennedy and Bouchard Reference Kennedy and Bouchard2010:112). At their base camp, they dried the meats and other roots before canoeing back home.

In a drawing, Johnny Jones / Yaqalatqa7 (Jones Reference Jones2011) depicts Líĺwat oral traditions related to the Qẃelqẃelústen area (Figure 3). His depiction is in the style of pictographic art; the original is even drawn in the color of red ochre, which pervades Líĺwat territory at important locales. Jones has created several drawings for numerous parts of their territory, which have been featured in roadside kiosks throughout the region and published in an archaeological publication (Jones Reference Jones2011). In the drawing for Qẃelqẃelústen, Jones depicts the mountain as an active and dangerous spirit in the landscape, with a spiral vortex at its center and forked tongues leading paths down its slopes. The recent debris avalanche and landslide of 2010, the largest in Canadian history (Roberti et al. Reference Roberti, Ward, van Wyk de Vries, Falorni, Menounos, Friele and Williams-Jones2018) along the southern Capricorn Creek is shown as reaching downriver along Meager Creek and the Upper Lillooet River (see Figures 2 and 3). Two other whorls indicate the location of the main tsek, or hot springs, on the eastern and southeastern flanks.

Figure 3. Drawing of the storied landscape of the Upper Lillooet River Valley by Johnny Jones (Reference Jones2011).

He depicts mountain goats just southwest of the mountain, with hunters actively shooting them with bows and arrows. People seeking power would also leap across the river's narrow and deep chasm that is just upriver from Múmleq, or above Keyhole Falls, as part of a rite of passage. The slit is quite narrow (about 3–4 m at the shortest point), yet some Líĺwat seeking power would jump across the gorge; Dick (Reference Dick, Angelbeck, Sanders and Hall2011) referred to these as scwená7em, or shamans—individuals undergoing spiritual training. To fail the jump across meant falling into the crevasse and into the river unseen below, which loudly courses through the narrow walls to its outlet at Múmleq (Keyhole Falls), dropping about 50 m to shallow pools below. In other words, it meant falling to one's death. Charlie Mack also indicated that mountain goat hunters would jump across the narrows to ascend Mount Meager. In the drawing, Jones depicts the jumping-across point (Bouchard and Kennedy Reference Bouchard and Kennedy2003:10).

Near the edge of the falls overlook is a rockshelter that likely was associated with scwená7em, given that one was near views of the Upper Lillooet River valley from above the falls and near views of the peaks of Qẃelqẃelústen (Sheppard et al. Reference Sheppard, Angelbeck, Sanders and Hall2015). Indeed, one member of the community, Tony James (Reference James, Angelbeck, Sanders and Hall2011), relayed how he had stayed at the rockshelter above the falls during one of his “trainings”; this training relates to physical strengthening and endurance as well as the quest for spirit powers.

For Líĺwat, the Qẃelqẃelústen area was a home for not only mountain goat but also grizzly bears, moose, and elk, which had migration corridors throughout, as recounted by Edwin “Buckshot” Bikadi (Reference Bikadi, Angelbeck, Sanders and Hall2011). Indeed, several rockshelter camps are located along the river at Qẃelqẃelústen's base, enough for a large party of hunters or other seasonal camping (Sheppard et al. Reference Sheppard, Angelbeck, Sanders and Hall2015). The area is also historically known for where the Líĺwat battled Chilcotin invaders. In one account by Harry Dick (Reference Dick, Angelbeck, Sanders and Hall2011), Líĺwat warriors killed all of the members of the raiding party with the exception of one so that he could return home to tell of their failure; that is, it is a historic account involving the Qẃelqẃelústen area that is about defending Líĺwat traditional territory.

Together, these Líĺwat narratives weave Qẃelqẃelústen / Mount Meager and Múmleq / Keyhole Falls into multiple aspects of their heritage: into their oral histories (battles), into the settings about their traditional subsistence use (mountain goat hunting), and into particular places regarded as áx7a, or having spiritual power (sacred). Indeed, it is the first significant geographic marker noted in the telling of the Copper Canoe myth, the journey that transformed Líĺwat traditional territory into the landscape known today and that is connected with the drawing up of salmon into their territory, one of the core components of their traditional subsistence livelihood.

Even today, Qẃelqẃelústen remains an important part of Líĺwat concern. It is a focal point for the northern part of their traditional territory of the Upper Lillooet River watershed. In the Líĺwat Land Use Plan (Líĺwat Nation Reference Nation2006), they recognize the area as one of their a7×7úlm'ecw, translated as areas of “spirited ground.” This means that any work proposed for the area requires studies to ensure the continuity of Líĺwat practices, whether concerning hunting, gathering, or spirituality. Líĺwat Nation is protective of its territory and the archaeological heritage contained within it, often to the point of activism, such as establishing blockades (Angelbeck and Jones Reference Angelbeck and Jones2018).

This overview of oral traditions, histories, and archaeologies indicates how prominent Qẃelqẃelústen has been and how it remains important for Líĺwat people. The story of the climbing of the mountain by ancient Líĺwat is one thread of many that are woven into the territory about the area. In this way, Qẃelqẃelústen is a chronotope in which narratives are tied materially to sites in the landscape; as Keith Basso (Reference Basso1996) described for Apache territory, these chronotopes are where “wisdom sits in places.” Yet, because these are storied locations, this does not mean that only wisdom is contained within the stories. Rather, broader forms of traditional knowledge are also present in them. In a related work, we have published an account of how Líĺwat oral histories provide insights and additional formation regarding the eruption of Mount Meager in 2360 cal BP (Wilson et al. Reference Wilson, Angelbeck and Jones2024). The narrative of Líĺwat climbers seeing the ocean prior to its eruption is one that contains an avenue to be tested for supporting evidence in its claims, as we proceed to do in the this article. First, we set the context of oral traditions concerning volcanoes throughout the Northwest.

Oral History Correlations with Western Scientific Approaches

In northwestern North America, there have been several studies that examine the correlations between Indigenous oral traditions and those of Western scientific approaches. This indicates that this is a growing field of investigation, given that Indigenous oral histories provide a broad set of potential avenues of investigation in relation to the past.

Rick Budhwa (Reference Budhwa2002, Reference Budhwa, Mackenthun and Mucher2021) conducted studies of the relationships between the 6850 cal BP eruption of Mount Mazama (in Oregon; known as Giiwas by the Klamath and Modoc peoples), the Bonneville landslide circa 900–400 cal BP (Washington State), and the earthquake and tsunami of AD 1700 in relation to Indigenous oral histories of the Northwest. He found that oral histories record details from past events that can be used to aid scientific approaches. As he put it, “a combination of the two perspectives may yield a richer, more holistic view of the past” (Budhwa Reference Budhwa2002:iii). McMillan and Hutchinson (Reference McMillan and Hutchinson2002) compiled numerous oral histories concerning earthquakes and tsunami and showed how they were described in numerous Indigenous oral narratives of the West Coast of North America throughout the Holocene. They showed how these were not only remembered through stories but also relayed through their arts and ritual ceremonies, indicating the importance of their impact on these communities. This is especially the case for instances of village abandonment due to such events (e.g., Hutchinson and McMillan Reference Hutchinson and McMillan1997). Similarly, Moodie and Catchpole (Reference Moodie and Catchpole1992) detail how Athapaskan oral traditions of a volcanic eruption correlate with the White River Basin eruption in AD 720, necessitating the widespread relocation of villages. Such approaches to integrating Western and Indigenous knowledges is becoming increasingly common (e.g., Mackenthun and Mucher Reference Mackenthun and Mucher2021).

Wilson and Harris (Reference Wilson, Harris, Fedje and Mathewes2005) provide numerous symmetries between Haida oral histories and Western scientific paleoenvironmental histories. Some narratives describe a period prior to the growth of trees, suggesting human presence early in the Holocene, which correlates with archaeological evidence (Fedje and Mathewes Reference Fedje and Mathewes2005). De Laguna (Reference De Laguna1958) has reported on correlations of glaciological history with the Tlingit oral histories, whereas Le Moigne and colleagues (Reference Le Moigne, Williams-Jones, Vigouroux and Russell2022) established the chronology of Canada's second most recent volcanic eruption (Sii Aks / Tseax) by integrating geological data with observational information recorded in the Nisga'a Adaawak (Nisga'a histories). Cruikshank (Reference Cruikshank2001) has described how oral traditions provide perspectives on the geological history of glaciers, arguing that Indigenous traditions can provide information for scientific research of paleoenvironments that are useful for understanding climate change, and that these traditions are necessarily important for being the only human histories available about such times. As she has emphasized, “It is no longer a question of whether oral tradition includes historical knowledge, but how much is present, how long a time span it covers, and how valid it is” (Cruikshank Reference Cruikshank1981:68).

Other scholars have documented how Indigenous oral traditions contain not only environmental information from the past but also details about social histories. In the Tsimshian area, oral traditions largely recorded by William Beynon—a Tsimshian scholar who worked with Boas and Barbeau—provided great historical details about battles waged with Tlingit groups to the north (Barbeau et al. Reference Barbeau, Beynon, Cove and MacDonald1987a, Reference Barbeau, Beynon, MacDonald and Cove1987b). The accounts contained evidence of village abandonment, the construction of forts, and the retaking of territories. The stories were so detailed—with village locations, names of warriors, and strategies deployed—that many scholars surmised that these might only be about battles waged just prior to Euro-American contact. Yet, Martindale and Marsden (Reference Martindale and Marsden2003) showed that archaeological evidence indicated that these battles occurred 1,500 to 2,000 years ago. Furthermore, Edinborough and colleagues (Reference Edinborough, Porčić, Martindale, Brown, Supernant and Ames2017) assessed Tsimshian oral traditions regarding population reductions in the Prince Rupert Harbour, finding that these correlated with the radiocarbon dates from the area. Such case studies indicate that oral historical knowledge can be passed along for multiple generations and still be very useful for archaeological understandings. All of these studies add some weight to the Delgamuukw case, which allowed oral histories to be submitted as evidence in courts in Canada (e.g., see Thom Reference Thom2001a, Reference Thom2001b).

Despite some opposition to the use of oral tradition in archaeology (Mason Reference Mason2000), Echo-Hawk (Reference Echo-Hawk2000) and Whiteley (Reference Whiteley2002) have argued that there is much to be gained from archaeologists engaging in dialogue with Indigenous oral traditions for a better and more well-rounded understanding of the past. In the spirit of these works, we aim to highlight how this Líĺwat oral history recounts evidence of past geological and volcanic knowledge of Mount Meager.

The Eruptive History of Qẃelqẃelústen

Qẃelqẃelústen, or the Mount Meager Volcanic Complex, is a large glaciated massif that developed over a period of about 2 mya and is characterized by long-lived volcanic activity, substantial uplift, and numerous large-scale landslides. It is located near the northern end of the Garibaldi Volcanic Belt, which itself represents the northern segment of the Cascade Volcanic Arc, formed by subduction of the Juan de Fuca Plate beneath the North American Plate (e.g., Russell et al. Reference Russell, Edwards, Williams-Jones and Hickson2023). Prominent peaks include Devastator Peak, Pylon Peak, Mount Job, Capricorn Mountain, Mount Meager, and Plinth Peak; for comparison of heights, several of the volcanoes have prominent peaks throughout the Cascade Range (Table 1; see also Figure 2). Eruptive volcanic materials from Mount Meager are compositionally diverse, ranging from basalts to rhyodacites, and they include both lava flows and explosive fragmental deposits (e.g., Andrews et al. Reference Andrews, Russell and Stewart2014; Harris et al. Reference Harris, Russell, Muhammad and Williams-Jones2022; Read Reference Read1977, Reference Read1990; Simpson et al. Reference Simpson, Stasiuk, Shimamura, Clague and Friele2006). Due to the extensive periods of glaciation and limited exposures and preservation of volcanic deposits, there is still only an incomplete eruptive history; a number of modern 40Ar/39Ar ages for basaltic to rhyodacite effusive and explosive products have been recently reported (~440, 200, 106, 24, and 17 ka; Harris et al. Reference Harris, Russell, Wilson and Jicha2023; Russell et al. Reference Russell, Stewart, Wilson and Williams-Jones2021).

Table 1. Prominent Volcanic Peaks of the Cascade Volcanic Arc, Sorted by Height, in Comparison with Qẃelqẃelústen / Mount Meager Volcanic Complex Peaks.

The most recent dated eruption of Qẃelqẃelústen occurred circa 2360–2332 cal BP, originating from a vent on the slope of Plinth Peak, with an eruptive cloud column likely reaching up to 14–18 km, where it interacted with the jet stream (e.g., Andrews et al. Reference Andrews, Russell and Stewart2014; Hickson et al. Reference Hickson, Russell and Stasiuk1999). The resulting Bridge River tephra was deposited as a still-recognizable stratum as far east as central Alberta (Clague et al. Reference Clague, Evans, Rampton and Woodsworth1995; Jensen et al. Reference Jensen, Beaudoin, Clynne, Harvey and Vallance2019; Mathewes and Westgate Reference Mathewes and Westgate1980; Westgate et al. Reference Westgate, Smith, Tomlinson, Smith and Smith1970). The eruption may have been associated with one or more edifice (flank and/or summit) collapses, well documented for andesitic to dacitic stratovolcanoes (e.g., Begét and Kienle Reference Begét and Kienle1992; Lipman and Mullineaux Reference Lipman and Mullineaux1981; Siebert Reference Siebert1984, Reference Siebert, Evans and DeGraff2002). Pyroclastic density currents from this eruption led to the formation of an impermeable roughly 110 m high dam that blocked the Upper Lillooet River, creating a temporary lake that swelled up to 780 m asl, with an estimated volume of approximately 0.55 km3 of water that lasted for about two months. Continued rise of the lake eventually led to catastrophic failure of the dam, resulting in a flood outburst that carved through the dam (Andrews et al. Reference Andrews, Russell and Stewart2014). Remnants of this event are seen in the narrow slit of Múmleq / Keyhole Falls, located at the southeast base of Qẃelqẃelústen. The assemblage comprises a series of lithologies representing different eruptive styles, from oldest to youngest: (1) pyroclastic airfall from five phases of eruption separated by short time intervals, each evolving from phreatomagmatic to magmatic activity; (2) pyroclastic block and ash flow with entrained charred logs and pumice blocks; and (3) dacite lavas. Atop these is a volcanic debris flow (Hickson et al. Reference Hickson, Russell and Stasiuk1999; Stasiuk and Russell Reference Stasiuk and Russell1990).

Major flank collapses have occurred at the Mount Meager Volcanic Complex repeatedly through the Holocene and likely close in time to the most recent eruption, around 2360 cal BP. Although most of the collapses were probably not associated with eruptions, these processes continue today with both major landslides and debris flows.Footnote 4 Evidence indicates that the volcano experienced multiple episodes of flank collapse throughout the Holocene, with lahars flowing into the Lillooet drainage. According to a summary by Friele and colleagues (Reference Friele, Jakob and Clague2008), about 25 landslides have been documented over the last 8,000 years. Of particular note is the 2010 Capricorn Creek landslide, which, at 53 million m3, is the largest landslide in Canadian recorded history. Occurring along Qẃelqẃelústen's southern flank, the landslide caused the temporary damming of the Upper Lillooet River and Meager Creek and forced the evacuation of more than 1,500 residents downriver in Pemberton (e.g., Guthrie et al. Reference Guthrie, Friele, Allstadt, Roberts, Evans, Delaney, Roche, Clague and Jakob2012; Roberti et al. Reference Roberti, Ward, van Wyk de Vries, Falorni, Menounos, Friele and Williams-Jones2018). Currently, there are at least 27 slopes with volumes greater than 0.5 million m3 and that show evidence of active motion (Roberti et al. Reference Roberti, Ward, van Wyk de Vries, Falorni, Menounos, Friele and Williams-Jones2018). Combining estimates from the Holocene, this amounts to a minimum estimated volume of 3.6 billion m3 (or 3.6 km3) in debris that has failed from the Mount Meager Volcanic Complex within the last 8,000 years (Friele et al. Reference Friele, Jakob and Clague2008; Table 2). For comparison, 5.5 km3 of Socompa, a volcano in northern Chile, failed during a singular 6180 cal BP sector collapse event, lowering the summit height by approximately 400 m (Grosse et al. Reference Grosse, Danišík, Apaza, Guzmán, Lahitte, Quidelleur and Self2022). In Mount St. Helens's eruption in 1980, 0.51 km3 of material was lost in landslides, which also reduced its height by 400 m (Brantley and Myers Reference Brantley and Myers2000).

Table 2. Major Volcanic Landslides Identified over the Last 8,000 Years in the Qẃelqẃelústen Area.

Note: Data compiled from Friele and colleagues (Reference Friele, Jakob and Clague2008), with the addition of the 2010 Capricorn Creek volume details from Guthrie and colleagues (Reference Guthrie, Friele, Allstadt, Roberts, Evans, Delaney, Roche, Clague and Jakob2012).

This geological history of Qẃelqẃelústen is characterized by repeated explosive and effusive volcanism in conjunction with widespread glaciation and numerous large-volume flank failures. It is therefore plausible that Qẃelqẃelústen may have been much higher and in line with Dick's statement that it was the “highest mountain” in Líĺwat territory. The history also reveals that the eruptive events continued to alter and shape the Upper Lillooet River valley. There are clear parallels to Líĺwat descriptions of the mountain, suggesting its prominent role in shaping the upper parts of their territory. Next, we assess correlations of this geological history with Líĺwat oral traditions through viewshed analyses.

Methodology for Viewshed Analyses

Viewshed analyses, or visibility analyses, have been increasingly used in archaeology to understand perspectives concerning the visibility of monuments or culturally important landscape features from certain vantage points (Llobera Reference Llobera2003; Wheatley and Gillings Reference Wheatley, Gillings and Lock2000; Whiteley Reference Whiteley2002). Some have applied viewshed analyses to understand settlement placement—as among the Iroquois (Jones Reference Jones2006) or Wari (Marsh and Schreiber Reference Marsh and Schreiber2015)—and the visibility of Chacoan tower kivas in the Southwest (Kantner and Hobgood Reference Kantner and Hobgood2016). As well, viewshed analyses have been used for evaluating the intervisibility of sites (Bernardini and Peeples Reference Bernardini and Peeples2015; Wheatley Reference Wheatley, Lock and Stančič1995) or sightlines for better defensive lookouts or fortifications (Conolly and Lake Reference Conolly and Lake2006:229; Keeley et al. Reference Keeley, Fontana and Quick2007:70–72).

In the Northwest Interior, within the broader Lillooet territory—of which Líĺwat are a part—Sakaguchi, Morin, and Dickie (Reference Sakaguchi, Morin and Dickie2010) have applied such analyses to understand the defensibility of pithouse villages that were situated on high, steep terraces in the Fraser Canyon. To the northwest of the Líĺwat region, Maschner (Reference Maschner, Aldenderfer and Maschner1996) has applied viewshed analyses to assess the placement of plankhouse villages among the Tlingit, whereas to the southeast, Supernant (Reference Supernant2014) assessed intervisibility of rock-walled sites along the Fraser River. Furthermore, Le Moigne and colleagues (Reference Le Moigne, Williams-Jones, Vigouroux and Russell2022) used viewshed analyses to determine the minimum height estimates of volcanic eruption plumes visible from Nisga'a villages in the Nass Valley. These studies indicate the variety of applications and show how viewshed analyses can enhance our understandings of human perspectives in the past. For such reasons, Wheatley (Reference Wheatley2004) has made the following argument:

Viewshed analyses begin from the human-scale experience of existing in the physical and social world. As such, they contribute to the formulation of substantive approaches to issues as diverse as cognitive perception, culture/nature dichotomy, visualism and sensory primacy, temporality and directionality [Wheatley Reference Wheatley2004].

This study is therefore one of only a few using viewshed analyses to assess the viability of oral traditions. It is one that explicitly states that something in particular (the ocean) could be seen from a specific vantage point (Qẃelqẃelústen/Mount Meager), sometime prior to a singular event long ago (the ca. 2360 cal BP eruption).

To examine visibility from Qẃelqẃelústen as described in Líĺwat oral tradition, we conducted viewshed analyses from various elevations, beginning at 2,680 m asl—the current highest point within the Mount Meager Volcanic Complex at Plinth Peak—to a height of 3780 m asl. The observer was symbolized as an arced polyline feature, rather than a single point, using the drawing tool in ArcMap. We chose a polyline feature for two reasons. First, the direction is generally westward. Second, we assumed that an observer or observers could have been standing anywhere on the peak or its upper west slope facing the Salish Sea. The polyline feature was placed at the general location of the last known eruption of Qẃelqẃelústen (ca. 2360 cal BP) at the current elevation of its highest point of Plinth Peak (2,680 m asl).

We used ArcMap on the ArcGIS 10.7 platform to calculate viewsheds from the point of view of observers standing at the height of the polyline. A total of nine viewshed analyses were conducted. To account for changes in the distance to the horizon as observer elevation increased, the Earth curvature option was engaged for each analysis. We constrained the viewshed analyses in two ways: (1) we limited the horizontal angle of the observer's scan, and (2) we applied a maximum viewing distance or radius. We limited the horizontal angle of the observer's scan to 150° between 150° and 300° in the polyline feature attribute table to focus toward the Salish Sea and its inlets, which is generally westward to southwestward. This was done to decrease calculation time and because there is no ocean to view beyond those parameters.

The viewing distance or radius was based on the maximum distance to the horizon from a given location, based on the elevation above sea level; the heights of the upper peaks of the Mount Meager massif range from to 2,627 m (Devastator Peak) to 2,680 m (Plinth Peak) above sea level (see Table 2). These constraints allowed for the determination of what was potentially visible from a given point and precluded issues with edge effects on the calculated viewsheds. In some cases, the calculated viewing distances resulted in viewsheds with significant coverage. Because context plays a significant role in identification (Bar Reference Bar2004; Oliva and Torralba Reference Oliva and Torralba2007; Palmer Reference Palmer1975), it is likely that even small patches of ocean would have been recognizable from an extreme distance and elevation, especially given sea color or the reflections of sunlight. Moreover, Líĺwat were familiar with routes to the sea, given that oral traditions recount travels to Coast Salish villages along numerous inlets of the Salish Sea for visits and trade (Kennedy and Bouchard Reference Kennedy and Bouchard2010:78–91); such travelers are depicted in the drawing by Jones (see Figure 3).

The digital elevation models (DEMs) for the viewshed analyses were downloaded from the Natural Resources of Canada GeoGratis website (GeoGratis 2020). The tiles were mosaicked into a single DEM with a Transverse Mercator projection, resulting in surface map portrayals (Figure 4).

Figure 4. Surface map of post-eruption Mount Meager massif: (a) view of northern aspect and (b) view of southern aspect.

Viewshed Analysis Results

Four of the nine viewshed analyses conducted were positive for visibility of the ocean (Table 3). First, we provide a viewshed from the current height from the highest point of the massif, Plinth Peak, at 2,680 m (Figure 5). A small patch of the Salish Sea first barely becomes visible at an elevation of 3,580 m asl, or 900 m above current maximum height. However, it is an extremely constrained area, revealing only a few hundred meters. This is likely to be unnoticed or confused with a small lake. It is more likely that the oral tradition refers to individuals at a slightly higher elevation, 950 m higher, from which a greater stretch of ocean is visible along the shoreline and reveals a sliver across the Strait of Georgia in the Salish Sea, from 3,630 m asl (Figure 6a). The area of the Salish Sea that becomes visible is off the east coast of Vancouver Island, south from the southeastern tip of Texada Island, near Nanoose Bay. In total, about a 1 km wide stretch of the sea is visible in two portions along the Vancouver Island shoreline, which extends into the Salish Sea for a length of 5 km.

Table 3. Results of Viewshed Analyses from Increasing Heights above the Current Volcanic Massif.

Figure 5. Viewshed analysis from current highest viewpoint at 2,680 MASL. Note: no visibility of the Salish Sea is possible.

Figure 6. Viewshed analyses from the vantage point of Mount Meager massif: (a) viewshed analysis from 950 m above current mountain height (2,680 m asl), indicating visibility of the Salish Sea; (b) viewshed analysis from 1,000 m above current mountain height, indicating greater visibility of the Salish Sea.

With an additional 50 m in elevation, or 1,000 m above its current height, the view of the ocean expands much farther (Figure 6b). Viewable portions include two apertures, involving 2 km and 2.5 km wide corridors for a total of about 4.5 km wide stretches of the Salish Sea along the shoreline; the stretches extend for 10 km, nearly one-third of the distance across the Salish Sea in that section.

Although those stretches of 4.5 km may seem slim on the maps, note that these stretches of visibility encompass about 2° of the viewshed horizon overall. For comparison, the moon and sun each comprise only a half a degree of the skyline, so these 4.5 km stretches could be envisaged as four lengths of the moon on the horizon. Note also that the ocean would not be confused with other bodies of water, given that there are no large lakes between the volcano and the ocean. Such stretches of water would also be highlighted in reflecting the available sunlight, standing out among the other features of the viewscape. Furthermore, the stretches of visibility involve 5 km and 10 km long stretches—at 950 and 1,000 m higher elevations, respectively—extending up to one-third of the entire width of the Salish Sea in that section of the coast. Here, we have primarily considered the minimal heights for visibility; further heights in elevation would only increase the visibility of the Salish Sea even more. We should note that some fluctuations in the height needed for the visibility of oceans also may be affected by atmospheric refraction of light, as with the optical dynamics of mirages, when hotter temperatures can elevate an image on the horizon. Moreover, if over 5,000 years ago, as is possible here, the sea levels may have been up to 200 m higher (Mackie et al. Reference Mackie, Fedje and McLaren2018), which also would reduce the height needed to some degree.

We find that these results are significant both culturally and geologically. With respect to their cultural significance, they suggest that the Líĺwat oral tradition regarding visibility from Qẃelqẃelústen is at least 2,400 years old, and likely much older, given the volatility of the mountain and its long history of debris landslides throughout the Holocene, as documented between 4,000 and 8,000 years ago (see Table 2). Furthermore, ancestral Líĺwat understood the broader cultural landscape of which they were a part through travel and trade networks reaching the inlets (Teit Reference Teit1906:232), so the small patches of ocean that were visible would be understood to be saltwater amid known features of the landscape. These results highlight the familiarity of high-elevation terrain for peoples of the Pacific Northwest (Mierendorf Reference Mierendorf1999; Reimer Reference Reimer2000, Reference Reimer and Carlson2003).

Interestingly, the main saltwater areas with which they would have been familiar through trade and kinship relations are not visible from the Mount Meager Volcanic Complex. The inlets that cut into the western flank of the Coastal Range—Bute Inlet, Toba Inlet, Jervis Inlet—were important trade conduits for Coastal and Interior groups, and the Líĺwat were familiar with these waterways (Kennedy and Bouchard Reference Kennedy and Bouchard2010:79–91; Teit Reference Teit1906:232). Their invisibility from Qẃelqẃelústen is due to the height of the coastal ranges combined with the deeply incised nature of the fjord-like inlets that spur off of the Salish Sea.

From a geological perspective, the results are also significant. They suggest that Qẃelqẃelústen may have lost as much as 950 m of its original height through volcanic eruption, landslides, and massive debris flows (e.g., Hickson et al. Reference Hickson, Russell and Stasiuk1999; Roberti et al. Reference Roberti, Ward, van Wyk de Vries, Falorni, Menounos, Friele and Williams-Jones2018). The proposed elevation of between approximately 3,500 and 3,700 m asl is not outside the realm of possibility given that other volcanoes within the Cascade Volcanic Arc are of similar or higher elevations (see Table 1). This could place the original height of Qẃelqẃelústen on the order of that of Mount Adams (3,743 m) or Mount Hood (3,429 m). A profile of the current peaks of Qẃelqẃelústen is shown along with the minimal height in which the Salish Sea is visible (Figure 7).

Figure 7. Profile view of Qẃelqẃelústen / Mount Meager prior to the approximately 2360 cal BP eruption, showing relative height of peaks in relation to the minimal height for visibility of the Salish Sea (3,630 m).

Based on the slopes of the extant peaks of the massif, there are some indications of the shape of the original mountain peak. The iteration heights for the visibility of the Salish Sea do appear to be readily possible. A mountain of such prominence would indeed have been of central importance within the whole of Líĺwat traditional territory, just as it features in its oral traditions. In this way, not only does the geological information align with the oral tradition, but the oral tradition provides information to better our understandings of the geological history of the massif.

Conclusion

Líĺwat oral traditions told today recount that climbers of the mountain, known as Qẃelqẃelústen, could see the ocean. This is not possible now, because peaks of Mount Meager Volcanic Complex have heights that are similar to surrounding peaks, and several mountain ridges obscure the view of the Salish Sea to the west. Yet, as we have presented here, it is plausible that the mountain’s height was significantly higher in the past, prior to its approximately 2360 cal BP eruption, when Líĺwat narratives hold that it was the highest peak in their territory. The results of our viewshed analysis indicate that one would have been able to see the ocean if the original height of the massif had been at least about 950 m higher and well within the range of other white-capped volcanoes of the Cascade Volcanic Arc. We maintain that this indicates that this Líĺwat oral tradition relays testimonies of the history prior to the volcano's eruption, and that this oral narrative is therefore well over 2,400 years old. Furthermore, because geological evidence suggests that the mountain's height was likely similar to that just prior to the 2360 cal BP eruption, the volume losses due to collapses and/or eruptions from 4,400 to 7,900 years ago more likely indicate the period for the greater height of the volcano (see Table 2).

The glaciers receded from the region over 11,000 years ago (Clague Reference Clague2017), and soon after that time, peoples ancestral to Líĺwat have occupied that territory. Their oral traditions, extending back to a Time of Transformation, recount how the landscape had been sculpted and shaped by major transformative events. For their Squamish neighbors adjacent to the west, Reimer (Reference Reimer2012) has argued for the similarities between oral histories of a period of great transformation and the paleoenvironmental histories of major changes at the close of the Pleistocene and the settlement of sea levels. For Líĺwat, a similar argument can be made about their histories of the Copper Canoe brothers, which tell of the shaping of their traditional territory during a time of geological transformation. Not only do Indigenous peoples of the Salishan area have oral histories of times long ago, but they also have a long familiarity with high montane landscapes, extending back many thousands of years. Reimer (Reference Reimer2000, Reference Reimer and Carlson2003) conveys this for the Squamish Coast Salish, whereas Mierendorf and Foit (Reference Mierendorf and Foit2018; also Mierendorf Reference Mierendorf1999) recount the long familiarity with mountain passes of the Upper Skagit Coast Salish and Interior Salish at Cascade Pass dating back over 9,000 years of high-alpine travel. These are among other examples, as discussed above.

All of these avenues—oral history, geological history, and viewshed analyses—intersect and combine to indicate that these Líĺwat oral traditions likely have substantial antiquity. Considering Occam’s Razor, we maintain that the simplest explanation for the convergence of these lines of evidence is that the oral history is based on testimony of Líĺwat climbers, likely mountain-goat hunters or shamans seeking power, who reached the peak earlier in the Holocene, prior to the large collapses and volcanic eruptions that formed the massif that stands today.

Acknowledgments

The authors wish to express their gratitude to Harry Dick, a knowledge holder of the oral histories of Qẃelqẃelústen, and to the members of the Líĺwat Nation who supported and facilitated this research—including Harriet VanWart, Maxine Joseph Bruce, and Roxanne Joe, and others from the Department of Land and Resources. Special thanks are extended to Ncat7aoq/Silas Pierre, who was instrumental in arranging our last interview with Mr. Dick, and to Jaime Yard (Douglas College) for her assistance in conducting the interview and providing valuable manuscript edits. We thank J. Kelly Russell (UBC) for his insights on the volcanological history of the Mount Meager Complex, and Nathalie Vigouroux-Caillibot (Douglas College) for her valuable perspectives and for facilitating our engagement with the Mount Meager volcanological research teams. Our appreciation also extends to Rudy Reimer / Yumks (SFU) and Rick Budhwa (Crossroads CRM) for their constructive comments on early drafts of our work. We also thank Daniel Proana Cepeda for translating our abstract into Spanish. Finally, we thank the anonymous reviewers and all who discussed this research with us, including all those whose research we cite, because those insights and efforts have been invaluable.

Funding Statement

This research received no specific grant funding form any funding agency, commercial, or not-for-profit sectors.

Data Availability Statement

All data underlying the results are available as part of the article and no additional source data are required.

Competing Interests

The authors declare none.

Footnotes

1. Given that Líĺwat refer to this mountain as Qẃelqẃelústen, we will primarily use this name. In our view, it is the original name, and it has substantial antiquity, as indicated in Líĺwat oral traditions. In contrast, the settler name was applied in 1923; they simply named it after J. B. Meager, who held timber licenses along its southern slopes. Because Líĺwat never ceded their territory to Canada through treaty, despite colonial settlement of their territory, it is preferable to use their name for the mountain. See Reimer (Reference Reimer2018), who advocates for the primary use of Indigenous names rather than settler ones.

2. He told this story after he, along with Kennedy and Bouchard (Reference Kennedy and Bouchard2010:13–15), was attempting to land on top of Qẃelqẃelústen in a helicopter. He had wanted to show them this important mountain. However, once they approached its peak, he had second thoughts because he saw the strong winds blowing across the summit of the massif, so he told the pilot, “No . . . don't land the helicopter.” Mack realized that the power and danger of the mountain should be respected.

3. Numerous Northwest groups have oral traditions about massive fish weirs that blocked the upriver ascent of salmon during the Time of Transformation (Ritchie and Angelbeck Reference Ritchie and Angelbeck2020).

References

References Cited

Abraham, Marie. 2000. Lil’wat Place Names. Líĺwat Nation Archives, Mount Currie, British Columbia.Google Scholar
Andrews, Graham D. M., Russell, James K., and Stewart, Martin L.. 2014. The History and Dynamics of a Welded Pyroclastic Dam and Its Failure. Bulletin of Volcanology 76(4):811.10.1007/s00445-014-0811-0CrossRefGoogle Scholar
Angelbeck, Bill, and Jones, Johnny. 2018. Direct Actions and Archaeology: The Lil'wat Peoples Movement to Protect Archaeological Sites. Journal of Contemporary Archaeology 5(2):219229.10.1558/jca.33578CrossRefGoogle Scholar
Angelbeck, Bill, and Yard, Jaime. 2022. Líĺwat Traditional Use and Knowledge of Qẃelqẃelústen/Mount Meager. Report prepared for Líĺwat Nation and Meager Creek Development Corporation. Líĺwat Nation Archives, Mount Currie, British Columbia.Google Scholar
Bar, Moshe. 2004. Visual Objects in Context. Nature Reviews Neuroscience 5(8):617629.10.1038/nrn1476CrossRefGoogle ScholarPubMed
Barbeau, Marius, Beynon, William, Cove, John J., and MacDonald, George (editors). 1987a. Tsimshian Narratives 1: Tricksters, Shamans, and Heroes. Mercury Series Paper No. 3. Canadian Museum of Civilization, Ottawa.Google Scholar
Barbeau, Marius, Beynon, William, MacDonald, George F., and Cove, John J. (editors). 1987b. Tsimshian Narratives 2: Trade and Warfare. Mercury Series Paper No. 3. Canadian Museum of Civilization, Ottawa.Google Scholar
Basso, Keith H. 1996. Wisdom Sits in Places: Landscape and Language among the Western Apache. University of New Mexico Press, Albuquerque.Google Scholar
Begét, James E., and Kienle, Juergen. 1992. Cyclic Formation of Debris Avalanches at Mount St. Augustine Volcano. Nature 356(6371):701704.10.1038/356701a0CrossRefGoogle Scholar
Bernardini, Wesley, and Peeples, Matthew A.. 2015. Sight Communities: The Social Significance of Shared Visual Landmarks. American Antiquity 80(2):215235.10.7183/0002-7316.80.2.215CrossRefGoogle Scholar
Bikadi, Edwin. 2011. Interview by Bill Angelbeck, Adrian Sanders, Johnny Jones, and Arnie Jim at Land and Resources Department, Mount Currie, B.C. on June 28, 2010. In Lilwat Traditional Use and Knowledge of the Upper Lillooet River Valley: A Traditional Use Study of the Proposed Upper Lillooet River Hydro Project Area, by Angelbeck, Bill, Sanders, Adrian, and Hall, Dave, pp. 234247. Lil’wat Nation and Arrowstone Archaeological Research and Consulting Ltd. for Creek Power. Lil’wat Nation Archives, Land and Resources Office, Mount Currie, British Columbia.Google Scholar
Bouchard, Randall, and Kennedy, Dorothy. 2003. Lilwat Traditional Knowledge and Use of the Upper Lillooet River. Report prepared for Creekside Resources Inc., Mount Currie, British Columbia.Google Scholar
Bouchard, Randall, Mack, Charlie, and Ritchie, Baptiste. 1975. Preliminary Map with Accompanying List of Lilwat Place Names, April 1975, Based on Information Provided by Charlie Mack, with Assistance of Baptiste Ritchie. B.C. Indian Language Project, Victoria, British Columbia.Google Scholar
Bovis, Michael J., and Jakob, Matthias. 2000. The July 29, 1988, Debris Flow and Landslide Dam at Capricorn Creek, Mount Meager Volcanic Complex, Southern Coast Mountains, British Columbia. Canadian Journal of Earth Sciences 37(10):13211334.10.1139/e00-042CrossRefGoogle Scholar
Brantley, Steven R., and Myers, Bobbie. 2000. Mount St. Helens–From the 1980 Eruption to 2000. Fact Sheet 036-00. US Geological Survey, Vancouver, Washington.10.3133/fs03600CrossRefGoogle Scholar
Budhwa, Rick. 2002. Correlations between Catastrophic Paleoenvironmental Events and Native Oral Traditions of the Pacific Northwest. Master’s thesis, Department of Archaeology, Simon Fraser University, Burnaby, British Columbia.Google Scholar
Budhwa, Rick. 2021. Witnessing Catastrophe: Correlations between Catastrophic Paleoenvironmental Events and First Nations’ Oral Traditions in North America’s Pacific Northwest. In Decolonizing “Prehistory”: Deep Time and Indigenous Knowledges in North America, edited by Mackenthun, Gesa and Mucher, Christen, pp. 89111. University of Arizona Press, Tucson.Google Scholar
Clague, John J. 2017. Deglaciation of the Cordillera of Western Canada at the End of the Pleistocene. Cuadernos de Investigación Geográfica 43(2):449466.10.18172/cig.3232CrossRefGoogle Scholar
Clague, John J., Evans, Stephen G., Rampton, Vern N., and Woodsworth, Glenn J.. 1995. Improved Age Estimates for the White River and Bridge River Tephras, Western Canada. Canadian Journal of Earth Sciences 32(8):11721179.10.1139/e95-096CrossRefGoogle Scholar
Conolly, James, and Lake, Mark. 2006. Geographical Information Systems in Archaeology. Cambridge University Press, Cambridge.10.1017/CBO9780511807459CrossRefGoogle Scholar
Cruikshank, Julie. 1981. Legend and Landscape: Convergence of Oral and Scientific Traditions in the Yukon Territory. Arctic Anthropology 18(2):6793.Google Scholar
Cruikshank, Julie. 2001. Glaciers and Climate Change: Perspectives from Oral Tradition. Arctic 54(4):377393.10.14430/arctic795CrossRefGoogle Scholar
De Laguna, Frederica. 1958. Geological Confirmation of Native Traditions, Yakutat, Alaska. American Antiquity 23(4):434434.10.2307/276497CrossRefGoogle Scholar
Dick, Harry. 2011. Interview with Harry Dick by Bill Angelbeck and Johnny Jones at Harry Dick’s home, Xito’lacw, B.C. on June 28, 2010. In Lilwat Traditional Use and Knowledge of the Upper Lillooet River Valley: A Traditional Use Study of the Proposed Upper Lillooet River Hydro Project Area, by Angelbeck, Bill, Sanders, Adrian, and Hall, Dave, pp. 259266. Lil’wat Nation and Arrowstone Archaeological Research and Consulting Ltd. for Creek Power. Lil’wat Nation Archives, Land and Resources Office, Mount Currie, British Columbia.Google Scholar
Echo-Hawk, Roger C. 2000. Ancient History in the New World: Integrating Oral Traditions and the Archaeological Record in Deep Time. American Antiquity 65(2):267290.10.2307/2694059CrossRefGoogle Scholar
Edinborough, Kevan, Porčić, Marko, Martindale, Andrew, Brown, Thomas Jay, Supernant, Kisha, and Ames, Kenneth M.. 2017. Radiocarbon Test for Demographic Events in Written and Oral History. PNAS 114(47):1243612441.10.1073/pnas.1713012114CrossRefGoogle ScholarPubMed
Evans, Stephen G. 1987. A Rock Avalanche from the Peak of Mount Meager, British Columbia. Geological Survey of Canada Paper 87-1A:929934.Google Scholar
Evans, Stephen G. 1992. Landslide and River Damming Events Associated with the Plinth Peak Volcanic Eruption, Southwestern British Columbia. In Geotechnique and Natural Hazards., edited by Peter Bobrowsky, pp. 405412. BiTech, Vancouver, British Columbia.Google Scholar
Fedje, Daryl W., and Mathewes, Rolf W. (editors). 2005. Haida Gwaii: Human History and Environment from the Time of Loon to the Time of the Iron People. UBC Press, Vancouver.Google Scholar
Friele, Pierre A., and Clague, John J.. 2004. Large Holocene Landslides from Pylon Peak, Southwestern British Columbia. Canadian Journal of Earth Sciences 41(2):165182.10.1139/e03-089CrossRefGoogle Scholar
Friele, Pierre A., and Clague, John J.. 2009. Paraglacial Geomorphology of Quaternary Volcanic Landscapes in the Southern Coast Mountains, British Columbia. In Periglacial and Paraglacial Processes and Environments, Special Publication 320, edited by Knight, Jasper and Harrison, Stephan, pp. 219233. Geological Society of London, London.Google Scholar
Friele, Pierre A., Jakob, Matthias, and Clague, John J.. 2008. Hazard and Risk from Large Landslides from Mount Meager Volcano, British Columbia, Canada. Georisk 2(1):4864.Google Scholar
GeoGratis. 2020. GeoGratis: Search, Discover and Download Free Maps, Data and Publications. Electronic document, http://www.geogratis.gc.ca/, accessed July 3, 2020.Google Scholar
Grosse, Pablo, Danišík, Martin, Apaza, Facundo D., Guzmán, Silvina R., Lahitte, Pierre, Quidelleur, Xavier, Self, Stephen, et al. 2022. Holocene Collapse of Socompa Volcano and Pre- and Post-Collapse Growth Rates Constrained by Multi-System Geochronology. Bulletin of Volcanology 84(9):85.10.1007/s00445-022-01594-0CrossRefGoogle Scholar
Guthrie, Richard H., Friele, Pierre, Allstadt, Kate, Roberts, Nicholas, Evans, Stephen G., Delaney, Keith B., Roche, David, Clague, John J., and Jakob, Matthias. 2012. The 6 August 2010 Mount Meager Rock Slide-Debris Flow, Coast Mountains, British Columbia: Characteristics, Dynamics, and Implications for Hazard and Risk Assessment. Natural Hazards and Earth System Sciences 12(5):12771294.10.5194/nhess-12-1277-2012CrossRefGoogle Scholar
Harris, Martin A., Russell, J. Kelly, Muhammad, Mahmud, and Williams-Jones, Glyn. 2022. Mount Meager Volcanic Complex, Garibaldi Volcanic Belt, British Columbia: Expanded Bedrock Map Including Cracked Mountain, North Lillooet Ridge, and West Mount Meager. Geological Survey of Canada Open File 8881. Electronic document, https://publications.gc.ca/collections/collection_2022/rncan-nrcan/m183-2/M183-2-8881-eng.pdf, accessed March 17, 2024.Google Scholar
Harris, Martin A., Russell, James K., Wilson, Alexander, and Jicha, Brian. 2023. A 500 ka Record of Volcanism and Paleoenvironment in the Northern Garibaldi Volcanic Belt, British Columbia. Canadian Journal of Earth Sciences 60(4):401421.10.1139/cjes-2022-0101CrossRefGoogle Scholar
Hetherington, Rachel M. 2014. Slope Stability Analysis of Mount Meager, South-Western British Columbia, Canada. Master's thesis, Department of Geological and Mining Engineering and Sciences, Michigan Technological University, Houghton, Michigan.Google Scholar
Hickson, Catherine J., Russell, J. Kelly, and Stasiuk, Mark V.. 1999. Volcanology of the 2350 B.P. Eruption of Mount Meager Volcanic Complex, British Columbia, Canada: Implications for Hazards from Eruptions in Topographically Complex Terrain. Bulletin of Volcanology 60(7):489507.10.1007/s004450050247CrossRefGoogle Scholar
Hutchinson, Ian, and McMillan, Alan D.. 1997. Archaeological Evidence for Village Abandonment Associated with Late Holocene Earthquakes at the Northern Cascadia Subduction Zone. Quaternary Research 48(1):7987.10.1006/qres.1997.1890CrossRefGoogle Scholar
James, Tony. 2011. Interview with Tony James by Bill Angelbeck, Adrian Sanders, and Johnny Jones at James’ Home in Lillooet, B.C., June 23, 2010. In Lilwat Traditional Use and Knowledge of the Upper Lillooet River Valley: A Traditional Use Study of the Proposed Upper Lillooet River Hydro Project Area, by Angelbeck, Bill, Sanders, Adrian, and Hall, Dave, pp. 283291. Lil’wat Nation and Arrowstone Archaeological Research and Consulting Ltd. for Creek Power. Lil’wat Nation Archives, Land and Resources Office, Mount Currie, British Columbia.Google Scholar
Jensen, Britta J. L., Beaudoin, Alwynne B., Clynne, Michael A., Harvey, Jordan, and Vallance, James W.. 2019. A Re-examination of the Three Most Prominent Holocene Tephra Deposits in Western Canada: Bridge River, Mount St. Helens Yn and Mazama. Quaternary International 500:8395.CrossRefGoogle Scholar
Joe, Louie. 2011. Interview. In Lilwat Traditional Use and Knowledge of the Upper Lillooet River Valley: A Traditional Use Study of the Proposed Upper Lillooet River Hydro Project Area, by Angelbeck, Bill, Sanders, Adrian, and Hall, Dave, pp. 283291. Lil’wat Nation and Arrowstone Archaeological Research and Consulting Ltd. for Creek Power. Lil’wat Nation Archives, Land and Resources Office, Mount Currie, British Columbia.Google Scholar
Jones, Eric E. 2006. Using Viewshed Analysis to Explore Settlement Choice: A Case Study of the Onondaga Iroquois. American Antiquity 71(3):523538.10.2307/40035363CrossRefGoogle Scholar
Jones, Johnny. 2011. Lil’wat Landscapes. Midden 43(1):49.Google Scholar
Kantner, John, and Hobgood, Ronald. 2016. A GIS-Based Viewshed Analysis of Chacoan Tower Kivas in the US Southwest: Were They for Seeing or to Be Seen. Antiquity 90(353):13021317.10.15184/aqy.2016.144CrossRefGoogle Scholar
Keeley, Lawrence H., Fontana, Marisa, and Quick, Russell. 2007. Baffles and Bastions: The Universal Features of Fortifications. Journal of Archaeological Research 15(1):5595.10.1007/s10814-006-9009-0CrossRefGoogle Scholar
Kennedy, Dorothy, and Bouchard, Randy. 2010. The Lilwat World of Charlie Mack. Talonbooks, Vancouver.Google Scholar
Le Moigne, Yannick, Williams-Jones, Glyn, Vigouroux, Nathalie, and Russell, James K.. 2022. Chronology and Eruption Dynamics of the Historic ~1700 CE Eruption of Tseax Volcano, British Columbia, Canada. Frontiers in Earth Science 10:910451. https://doi.org/10.3389/feart.2022.910451.CrossRefGoogle Scholar
Nation, Líĺwat. 2006. Líĺwat Land Use Plan: Phase 1-The Vision and Plan for the Land and Resources of Líĺwat Nation Traditional Territory. Líĺwat Nation, Mount Currie, British Columbia.Google Scholar
Lipman, Peter W., and Mullineaux, Donal Ray (editors). 1981. The 1980 Eruptions of Mount St. Helens, Washington. US Geological Survey Professional Paper 1250. US Department of the Interior, Washington, DC.10.3133/pp1250CrossRefGoogle Scholar
Llobera, Marcos. 2003. Extending GIS-Based Visual Analysis: The Concept of Visualscapes. International Journal of Geographical Information Science 17(1):2548.10.1080/713811741CrossRefGoogle Scholar
Mackenthun, Gesa, and Mucher, Christen (editors). 2021. Decolonizing Prehistory”: Deep Time and Indigenous Knowledges in North America. University of Arizona Press, Tucson.Google Scholar
Mackie, Quentin, Fedje, Daryl, and McLaren, Duncan. 2018. Archaeology and Sea Level Change on the British Columbia Coast. Canadian Journal of Archaeology 42(1):7491.Google Scholar
Marsh, Erik J., and Schreiber, Katharina. 2015. Eyes of the Empire: A Viewshed-Based Exploration of Wari Site-Placement Decisions in the Sondondo Valley, Peru. Journal of Archaeological Science: Reports 4:5464.Google Scholar
Martindale, Andrew R. C., and Marsden, Susan. 2003. Defining the Middle Period (3500 BP to 1500 BP) in Tsimshian History through a Comparison of Archaeological and Oral Records. BC Studies 138:1350.Google Scholar
Maschner, Herbert D. G. 1996. The Politics of Settlement Choice on the Northwest Coast: Cognition, GIS, and Coastal Landscapes. In Anthropology, Space, and Geographic Information Systems, edited by Aldenderfer, Mark and Maschner, Herbert D. G., pp. 175189. Oxford University Press, New York.Google Scholar
Mason, Ronald J. 2000. Archaeology and Native North American Oral Traditions. American Antiquity 65(2):239266.10.2307/2694058CrossRefGoogle Scholar
Mathewes, Rolf W., and Westgate, John A.. 1980. Bridge River Tephra: Revised Distribution and Significance for Detecting Old Carbon Errors in Radiocarbon Dates of Limnic Sediments in Southern British Columbia. Canadian Journal of Earth Sciences 17(11):14541461.10.1139/e80-153CrossRefGoogle Scholar
McMillan, Alan D., and Hutchinson, Ian. 2002. When the Mountain Dwarfs Danced: Aboriginal Traditions of Paleoseismic Events along the Cascadia Subduction Zone of Western North America. Ethnohistory 49(1):4168.10.1215/00141801-49-1-41CrossRefGoogle Scholar
Mierendorf, Robert R. 1999. Pre-Contact Use of the Tundra Zones of the Northern Cascade Range of Washington and British Columbia. Archaeology in Washington 7:323.Google Scholar
Mierendorf, Robert R., and Foit, Franklin F. Jr. 2018. Holocene Geochronology and Archaeology at Cascade Pass, Northern Cascade Range, Washington. Memoir 16. Journal of Northwest Anthropology, Richland, Washington.Google Scholar
Moodie, D. Wayne, and Catchpole, A. J. W.. 1992. Northern Athapaskan Oral Traditions and the White River Volcano. Ethnohistory 39(2):148171.10.2307/482391CrossRefGoogle Scholar
Oliva, Aude, and Torralba, Antonio. 2007. The Role of Context in Object Recognition. Trends in Cognitive Sciences 11(12):520527.10.1016/j.tics.2007.09.009CrossRefGoogle ScholarPubMed
Palmer, Stephen E. 1975. The Effects of Contextual Scenes on the Identification of Objects. Memory & Cognition 3(5):519526.10.3758/BF03197524CrossRefGoogle ScholarPubMed
Patton, Frank D. 1976. The Devastation Glacier Slide, Pemberton, B.C. (abstract). In Cordilleran Section, Geomorphology of the Canadian Cordillera and Its Bearing on Mineral Deposits, pp. 26–27. Geological Association of Canada, St. John's, Newfoundland.Google Scholar
Read, Peter B. 1977. Meager Creek Volcanic Complex, Southwestern British Columbia. Geological Survey of Canada Paper, 77–1A:277–281.Google Scholar
Read, Peter B. 1990. Mount Meager Complex, Garibaldi Belt, Southwestern British Columbia. Geoscience Canada 17(3):167170.Google Scholar
Reimer, Rudy (Yumks). 2000. Extreme Archaeology: The Results of Investigations at High Elevation Regions in the Northwest. Master’s thesis, Department of Archaeology, Simon Fraser University, Burnaby, British Columbia.Google Scholar
Reimer, Rudy (Yumks). 2003. Alpine Archaeology and Oral Traditions of the Squamish. In Archaeology of Coastal British Columbia: Essays in Honour of Professor Philip M. Hobler, edited by Carlson, Roy L., pp. 4559. Archaeology Press, Simon Fraser University, Burnaby, British Columbia.Google Scholar
Reimer, Rudy (Yumks). 2012. The Mountains and Rocks Are Forever: Lithics and Landscapes of Skwxwú7Mesh Uxwumixw. PhD, dissertation. Department of Anthropology, McMaster University, Hamilton, Ontario.Google Scholar
Reimer, Rudy (Yumks). 2018. The Social Importance of Volcanic Peaks for the Indigenous Peoples of British Columbia. Journal of Northwest Anthropology 52(1):435.Google Scholar
Ritchie, Morgan, and Angelbeck, Bill. 2020. “Coyote Broke the Dams”: Power, Reciprocity, and Conflict in Fish Weir Narratives and Implications for Traditional and Contemporary Fisheries. Ethnohistory 67(2):191220.10.1215/00141801-8025268CrossRefGoogle Scholar
Roberti, Gioachino, Ward, Brent, van Wyk de Vries, Benjamin, Falorni, Giacomo, Menounos, Brian, Friele, Pierre, Williams-Jones, Glyn, et al. 2018. Landslides and Glacier Retreat at Mt. Meager Volcano: Hazard and Risk Challenges. Paper presented at the Geohazards 7 Conference, Canadian Geotechnical Society, Canmore, Alberta. Electronic document, https://cgs.ca/docs/geohazards/canmore2018/GeoHazards2018/pdfs/geohaz149.pdf, accessed May 8, 2024.Google Scholar
Russell, James K., Edwards, Benjamin R., Williams-Jones, Glyn, and Hickson, Catherine J.. 2023. Pleistocene to Holocene Volcanism in the Canadian Cordillera. Canadian Journal of Earth Sciences 60(10):14431466.10.1139/cjes-2023-0065CrossRefGoogle Scholar
Russell, James K., Stewart, Martin, Wilson, Alex, and Williams-Jones, Glyn. 2021. Eruption of Mount Meager, British Columbia, during the Early Fraser Glaciation. Canadian Journal of Earth Sciences 58(10):11461154.10.1139/cjes-2021-0023CrossRefGoogle Scholar
Sakaguchi, Takashi, Morin, Jesse, and Dickie, Ryan. 2010. Defensibility of Large Prehistoric Sites in the Mid-Fraser Region on the Canadian Plateau. Journal of Archaeological Science 37(6):11711185.10.1016/j.jas.2009.12.015CrossRefGoogle Scholar
Sheppard, Jonathan E., Angelbeck, Bill, Sanders, Adrian, and Hall, Dave. 2015. Archaeological Impact Assessment (AIA) of the Proposed Upper Lillooet Hydro Project, Near Pemberton, B.C. Arrowstone Archaeological Research and Consulting; Land and Resources Department, Lil’wat Nation, Mount Currie, British Columbia.Google Scholar
Siebert, Lee. 1984. Large Volcanic Debris Avalanches: Characteristics of Source Areas, Deposits, and Associated Eruptions. Journal of Volcanology and Geothermal Research 22(3–4):163197.10.1016/0377-0273(84)90002-7CrossRefGoogle Scholar
Siebert, Lee. 2002. Landslides Resulting from Structural Failure of Volcanoes. In Catastrophic Landslides: Effects, Occurrence, and Mechanisms, edited by Evans, Stephen G. and DeGraff, Jerome V., pp. 209235. Geological Society of America, Boulder, Colorado.10.1130/REG15-p209CrossRefGoogle Scholar
Simpson, Kirstie A., Stasiuk, Mark, Shimamura, Kas, Clague, John J., and Friele, Pierre. 2006. Evidence for Catastrophic Volcanic Debris Flows in Pemberton Valley, British Columbia. Canadian Journal of Earth Sciences 43(6):679689.10.1139/e06-026CrossRefGoogle Scholar
Stasiuk, Mark V., and Russell, J. Kelly. 1990. The Bridge River Assemblage in the Meager Mountain Volcanic Complex, Southwestern British Columbia. Geological Survey of Canada Paper 90-1E:227233.Google Scholar
Supernant, Kisha. 2014. Intervisibility and Intravisibility of Rock Feature Sites: A Method for Testing Viewshed within and outside the Socio-Spatial System of the Lower Fraser River Canyon, British Columbia. Journal of Archaeological Science 50:497551.10.1016/j.jas.2014.08.008CrossRefGoogle Scholar
Teit, James. 1906. The Lillooet Indians. E. J. Brill, Leiden, Netherlands..Google Scholar
Teit, James. 1912. Traditions of the Lillooet Indians of British Columbia. Journal of American Folklore 25(98):287371.10.2307/534513CrossRefGoogle Scholar
Thom, Brian. 2001a. Aboriginal Rights and Title in Canada after Delgamuukw: Part One, Oral Traditions and Anthropological Evidence in the Courtroom. Native Studies Review 14(1):126.Google Scholar
Thom, Brian. 2001b. Aboriginal Rights and Title in Canada after Delgamuukw: Part Two, Anthropological Perspectives on Rights, Tests, Infringement & Justification. Native Studies Review 14(2):142.Google Scholar
Warwick, Rachel, Williams-Jones, Glyn, Kelman, Melanie, and Witter, Jeffrey. 2022. A Scenario-Based Volcanic Hazard Assessment for the Mount Meager Volcanic Complex, British Columbia. Journal of Applied Volcanology 11:5.10.1186/s13617-022-00114-1CrossRefGoogle ScholarPubMed
Westgate, John A., Smith, Dorian G. W., and Tomlinson, M.. 1970. Late Quaternary Tephra Layers in Southwestern Canada. In Early Man and Environments in Northwest North America, edited by Smith, Rachel A. and Smith, J. W., pp. 1334. University of Calgary Archaeological Association, Calgary, Alberta.Google Scholar
Wheatley, David. 1995. Cumulative Viewshed Analysis: A GIS-based Method for Investigating Intervisibility, and Its Archaeological Application. In Archaeology and Geographical Information Systems: A European Perspective, edited by Lock, Gary and Stančič, Zoran, pp. 171185. Taylor and Francis, London.Google Scholar
Wheatley, David. 2004. Making Space for an Archaeology of Place. Internet Archaeology 15.10.11141/ia.15.10CrossRefGoogle Scholar
Wheatley, David, and Gillings, Mark. 2000. Vision, Perception and GIS: Developing Enriched Approaches to the Study of Archaeological Visibility. In Beyond the Map: Archaeology and Spatial Technologies, edited by Lock, Gary, pp. 127. IOS Press, Amsterdam.Google Scholar
Whiteley, Peter M. 2002. Archaeology and Oral Tradition: The Scientific Importance of Dialogue. American Antiquity 67(3):405415.10.2307/1593819CrossRefGoogle Scholar
Wilson, (Kii7iljuus) Barbara J., and Harris, Heather. 2005. Tllsda Xaaydas K’aaygang.nga: Long, Long Ago Haida Ancient Stories. In Haida Gwaii: Human History and Environment from the Time of Loon to the Time of the Iron People, edited by Fedje, Daryl W. and Mathewes, Rolf W., pp. 121139. UBC Press, Vancouver.Google Scholar
Wilson, Michael C., Angelbeck, Bill, and Jones, Johnny. 2024 Líl'wat Oral Traditions of Qw̓elqw̓elústen (Mount Meager): Indigenous Records of Volcanic Eruption and Landscape Change in Southwest British Columbia. Canadian Journal of Earth Sciences, in press.10.1139/cjes-2023-0098CrossRefGoogle Scholar
Figure 0

Figure 1. Location of Qẃelqẃelústen / Mount Meager massif in south-central British Columbia.

Figure 1

Figure 2. Topographic map indicating current peaks of the Mount Meager Complex.

Figure 2

Figure 3. Drawing of the storied landscape of the Upper Lillooet River Valley by Johnny Jones (2011).

Figure 3

Table 1. Prominent Volcanic Peaks of the Cascade Volcanic Arc, Sorted by Height, in Comparison with Qẃelqẃelústen / Mount Meager Volcanic Complex Peaks.

Figure 4

Table 2. Major Volcanic Landslides Identified over the Last 8,000 Years in the Qẃelqẃelústen Area.

Figure 5

Figure 4. Surface map of post-eruption Mount Meager massif: (a) view of northern aspect and (b) view of southern aspect.

Figure 6

Table 3. Results of Viewshed Analyses from Increasing Heights above the Current Volcanic Massif.

Figure 7

Figure 5. Viewshed analysis from current highest viewpoint at 2,680 MASL. Note: no visibility of the Salish Sea is possible.

Figure 8

Figure 6. Viewshed analyses from the vantage point of Mount Meager massif: (a) viewshed analysis from 950 m above current mountain height (2,680 m asl), indicating visibility of the Salish Sea; (b) viewshed analysis from 1,000 m above current mountain height, indicating greater visibility of the Salish Sea.

Figure 9

Figure 7. Profile view of Qẃelqẃelústen / Mount Meager prior to the approximately 2360 cal BP eruption, showing relative height of peaks in relation to the minimal height for visibility of the Salish Sea (3,630 m).