Recent (7.6kya) deposit of volcanic ash in North America
The Mazama Ash (formally named the Mazama Member in some areas)[1] is an extensive, geologically recent deposit of volcanic ash that is present throughout much of northern North America. The ash was ejected from Mount Mazama, a volcano in south-central Oregon, during its climactic eruption about 7640 ± 20[4] years ago when Crater Lake was formed by caldera collapse. The ash spread primarily to the north and east due to the prevailing winds, and remnants of the ash have been identified as far northeast as the Greenland ice sheet.[5]
The ash particles and gasses from the Mazama eruption would have caused climate cooling for a period of several years after the eruption.[5] Throughout the northern Great Plains, the ash would have darkened the sky and a layer of ash at least several centimeters thick would have blanketed much of the landscape, causing severe disruptions for the native people and wildlife.[7][9]
The Mazama ash spread over an area of at least 900,000km2 (350,000sqmi) in the northern Great Plains, where it is most commonly preserved within peat, alluvial, lacustrine, and aeoliansediments.[11]
In Canada, deposits of Mazama Ash several centimeters thick are commonly present in southern areas of British Columbia,[13]Alberta, and Saskatchewan.[11] In southern Alberta, about 1000 kilometers (about 600 miles) northeast of the eruption site, the Mazama Ash is typically found as a white band located several metres below the present ground surface.[9] Shards of volcanic glass from the Mazama Ash have also been identified in the sediments of Lake Superior and in a bog in Newfoundland.[6]
Comparison with the effects of the Mount St. Helens eruption of 1980 indicates that the Mazama Ash would have covered the landscape in a blanket up to 15cm (6in) thick, coating vegetation and clogging watercourses throughout the ashfall area. This would have caused an immediate scarcity of resources for the native people and wildlife, necessitating the movement of people out of the main ashfall area. Available archeological evidence from a site in the Cypress Hills of southern Alberta suggests a hiatus in human occupation of the ash-affected area there of perhaps 200 years.[7][9]
The particles and gasses released during the Mazama eruption caused climate cooling. Studies of the Greenland ice core suggest that the eruption produced a substantial stratospheric aerosol loading spread over a period about 6 years. This may have produced a temperature depression of about 0.6 to 0.7°C at mid to high northern latitudes for 1 to 3 years. The release of chlorine during the eruption may also have led to substantial depletion of stratospheric ozone.[5]
See also
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Zdanowicz, C.M., Zielinski, G.A. and Germani, M.S. 1999. Mount Mazama eruption: Calendrical age verified and atmospheric impact assessed. Geology, vol. 27, no. 7, p. 621-624.
Spano, N.G., Lane, C.S., Francis, S.W. and Johnson, T.C. 2017. Discovery of Mount Mazama cryptotephra in Lake Superior (North America): Implications and potential applications. Geology, vol. 45, p. 1071-1074.
Oetelaar, G.A. and Beaudoin, A. 2005. Darkened skies and sparkling grasses: The potential impact of the Mazama ash fall on the northwestern Plains. Plains Anthropologist, vol. 50, no. 195, p. 285-305.
White, J.M. and Osborn, G. 1992. Evidence for a Mazama-like tephra deposited ca. 10 000 B.P. at Copper Lake, Banff National Park, Alberta; Fig. 1 (inset), p. 53. Canadian Journal of Earth Sciences, vol. 29, p. 52-62.
Beaudoin, A. and Oetelaar, G.A. 2014. Investigating the environmental impacts and cultural responses to the Mazama ashfall on the northern Plains. Geological Society of America, Abstracts with Programs, vol. 46, no. 6, p. 460.
Debret, M., Desmet, M., Balsam, W., Copard, Y., Francus, P. and Laj, C. 2006. Spectrophotometer analysis of Holocene sediments from an anoxic fjord: Saanich Inlet, British Columbia, Canada. Marine Geology, vol. 229, p. 15-28.
Theisen, A.A., Borchardt, G.A., Harward, M.E. and Schmitt, R.A. 1968. Neutron activation for distinguishing Cascade Range pyroclastics. Science, vol. 161, p. 1009-1011.
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