Late Holocene cryptotephra and a provisional 15 000-year Bayesian age model for Cascade Lake, Alaska
Multiple chronometers can be employed for dating Holocene palaeoenvironmental records, each with its own inherent strengths and weaknesses. Radiocarbon dating is one of the most widely used techniques for producing chronologies, but its application at high-latitude sites can sometimes be problematic...
| Published in: | Geochronology |
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| Format: | Article in Journal/Newspaper |
| Language: | English |
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Copernicus Publications
2022
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| Online Access: | https://doi.org/10.5194/gchron-4-121-2022 https://doaj.org/article/a456708ffaa449e18a85d8500322e524 |
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ftdoajarticles:oai:doaj.org/article:a456708ffaa449e18a85d8500322e524 |
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ftdoajarticles:oai:doaj.org/article:a456708ffaa449e18a85d8500322e524 2024-09-15T18:00:28+00:00 Late Holocene cryptotephra and a provisional 15 000-year Bayesian age model for Cascade Lake, Alaska L. J. Davies B. J. L. Jensen D. S. Kaufman 2022-03-01T00:00:00Z https://doi.org/10.5194/gchron-4-121-2022 https://doaj.org/article/a456708ffaa449e18a85d8500322e524 EN eng Copernicus Publications https://gchron.copernicus.org/articles/4/121/2022/gchron-4-121-2022.pdf https://doaj.org/toc/2628-3719 doi:10.5194/gchron-4-121-2022 2628-3719 https://doaj.org/article/a456708ffaa449e18a85d8500322e524 Geochronology, Vol 4, Pp 121-141 (2022) Geology QE1-996.5 Stratigraphy QE640-699 article 2022 ftdoajarticles https://doi.org/10.5194/gchron-4-121-2022 2024-08-05T17:49:42Z Multiple chronometers can be employed for dating Holocene palaeoenvironmental records, each with its own inherent strengths and weaknesses. Radiocarbon dating is one of the most widely used techniques for producing chronologies, but its application at high-latitude sites can sometimes be problematic. Here, cryptotephra were identified in a core from Cascade Lake, Arctic Alaska, and used to identify and resolve an age bias in Late Holocene radiocarbon dates from the top 1.42 m of the sediment sequence. Identifiable geochemical populations of cryptotephra are shown to be present in detectable concentrations in sediment from the north flank of the Brooks Range for the first time. Major-element glass geochemical correlations are demonstrated between ultra-distal cryptotephra and reference samples from the Late Holocene caldera-forming eruption of Opala, Kamchatka, as well as three eruptions in North America: the White River Ash (northern lobe), Ruppert tephra and the Late Holocene caldera-forming eruption of Aniakchak. The correlated ages of these cryptotephra provide evidence for an old-carbon effect and support preliminary palaeomagnetic secular variation (PSV) correlated ages reported for Cascade Lake. Chronological data from Cascade Lake were then combined using a Bayesian approach to generate an age–depth model that extends back through the Late Holocene and provisionally to 15 000 cal yr BP . Article in Journal/Newspaper Brooks Range Kamchatka Alaska Directory of Open Access Journals: DOAJ Articles Geochronology 4 1 121 141 |
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Directory of Open Access Journals: DOAJ Articles |
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English |
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Geology QE1-996.5 Stratigraphy QE640-699 |
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Geology QE1-996.5 Stratigraphy QE640-699 L. J. Davies B. J. L. Jensen D. S. Kaufman Late Holocene cryptotephra and a provisional 15 000-year Bayesian age model for Cascade Lake, Alaska |
| topic_facet |
Geology QE1-996.5 Stratigraphy QE640-699 |
| description |
Multiple chronometers can be employed for dating Holocene palaeoenvironmental records, each with its own inherent strengths and weaknesses. Radiocarbon dating is one of the most widely used techniques for producing chronologies, but its application at high-latitude sites can sometimes be problematic. Here, cryptotephra were identified in a core from Cascade Lake, Arctic Alaska, and used to identify and resolve an age bias in Late Holocene radiocarbon dates from the top 1.42 m of the sediment sequence. Identifiable geochemical populations of cryptotephra are shown to be present in detectable concentrations in sediment from the north flank of the Brooks Range for the first time. Major-element glass geochemical correlations are demonstrated between ultra-distal cryptotephra and reference samples from the Late Holocene caldera-forming eruption of Opala, Kamchatka, as well as three eruptions in North America: the White River Ash (northern lobe), Ruppert tephra and the Late Holocene caldera-forming eruption of Aniakchak. The correlated ages of these cryptotephra provide evidence for an old-carbon effect and support preliminary palaeomagnetic secular variation (PSV) correlated ages reported for Cascade Lake. Chronological data from Cascade Lake were then combined using a Bayesian approach to generate an age–depth model that extends back through the Late Holocene and provisionally to 15 000 cal yr BP . |
| format |
Article in Journal/Newspaper |
| author |
L. J. Davies B. J. L. Jensen D. S. Kaufman |
| author_facet |
L. J. Davies B. J. L. Jensen D. S. Kaufman |
| author_sort |
L. J. Davies |
| title |
Late Holocene cryptotephra and a provisional 15 000-year Bayesian age model for Cascade Lake, Alaska |
| title_short |
Late Holocene cryptotephra and a provisional 15 000-year Bayesian age model for Cascade Lake, Alaska |
| title_full |
Late Holocene cryptotephra and a provisional 15 000-year Bayesian age model for Cascade Lake, Alaska |
| title_fullStr |
Late Holocene cryptotephra and a provisional 15 000-year Bayesian age model for Cascade Lake, Alaska |
| title_full_unstemmed |
Late Holocene cryptotephra and a provisional 15 000-year Bayesian age model for Cascade Lake, Alaska |
| title_sort |
late holocene cryptotephra and a provisional 15 000-year bayesian age model for cascade lake, alaska |
| publisher |
Copernicus Publications |
| publishDate |
2022 |
| url |
https://doi.org/10.5194/gchron-4-121-2022 https://doaj.org/article/a456708ffaa449e18a85d8500322e524 |
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Brooks Range Kamchatka Alaska |
| genre_facet |
Brooks Range Kamchatka Alaska |
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Geochronology, Vol 4, Pp 121-141 (2022) |
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https://gchron.copernicus.org/articles/4/121/2022/gchron-4-121-2022.pdf https://doaj.org/toc/2628-3719 doi:10.5194/gchron-4-121-2022 2628-3719 https://doaj.org/article/a456708ffaa449e18a85d8500322e524 |
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https://doi.org/10.5194/gchron-4-121-2022 |
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Geochronology |
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4 |
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1 |
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121 |
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141 |
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