Arctic Alaska deepwater organic carbon burial and environmental changes during the late Albian–early Campanian (103–82 Ma)

•Enigmatic role of Arctic deepwater in middle Cretaceous greenhouse carbon cycle.•Alaska δ13Corg and 103–82 Ma ashes record global carbon isotope excursions (CIEs).•High marine productivity and organic carbon burial during several CIEs and Turonian.•Shift from saline OMZ to fresher euxinic basin rev...

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Published inEarth and planetary science letters Vol. 646; p. 118948
Main Authors Lease, Richard O., Whidden, Katherine J., Dumoulin, Julie A., Houseknecht, David W., Botterell, Palma J., Dreier, Mark F., Griffis, Neil P., Mundil, Roland, Kylander-Clark, Andrew R.C., Sanders, Margaret M., Counts, John W., Self-Trail, Jean M., Gooley, Jared T., Rouse, William A., Smith, Rebecca A., DeVera, Christina A.
Format Journal Article
LanguageEnglish
Published Elsevier B.V 15.11.2024
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Summary:•Enigmatic role of Arctic deepwater in middle Cretaceous greenhouse carbon cycle.•Alaska δ13Corg and 103–82 Ma ashes record global carbon isotope excursions (CIEs).•High marine productivity and organic carbon burial during several CIEs and Turonian.•Shift from saline OMZ to fresher euxinic basin reveals increased Arctic restriction.•Productive Arctic deepwater marine carbon sink despite evolving greenhouse conditions. The middle Cretaceous greenhouse period experienced profound environmental change including episodes of enhanced global burial of organic carbon marked by carbon isotopic excursions (CIEs). However, the role and response of polar regions like the newly formed, partially enclosed Arctic Ocean Basin during middle Cretaceous carbon burial remains enigmatic. We present the first Arctic deepwater CIE record that characterizes conditions offshore of the Alaska margin north of 75°N paleolatitude. Organic carbon isotopes (δ13Corg) and 103–82 Ma ash zircon U-Pb dates from the distal Hue Shale record multiple Albian–Campanian CIEs during slow ∼3–15 m/Myr sediment accumulation rates. Average total organic carbon (TOC) increased substantially during large 2–3 ‰ CIEs of the ∼101 Ma Albian-Cenomanian boundary event (from 7 to 18 % TOC) and ∼94 Ma Cenomanian-Turonian boundary event (5 to 10 % TOC). Turonian TOC remained elevated (8–13 %) during high global sea levels and temperatures of the Cretaceous Thermal Maximum, followed by an increase from 7 to 11 % TOC during the ∼90 Ma late Turonian event 1.5 ‰ CIE. Average TOC subsequently decreased in the Coniacian–Campanian, but relative maxima occurred during subtle 0.5–1 ‰ CIEs interpreted as the ∼87 Ma late Coniacian event (increase from 4 to 7 % TOC), ∼85 Ma Horseshoe Bay event (3.5 to 4.5 % TOC), and ∼84 Ma Santonian-Campanian boundary event (3.5 to 5 % TOC). Increases in hydrogen index and productivity proxies (P, Ba, Nd) that accompanied each CIE episode with enhanced TOC suggest a strong link between marine productivity and organic carbon burial at short-term CIE timescales. However, long-term (>5–8 Myr) changes in trace metal redox (Mo, Fe, V) and salinity (B/Ga) proxies suggest shifts in prevailing environmental conditions at timescales longer than the CIEs. Late Albian–middle Turonian marine salinity occurred during euxinic (103–98 Ma) and suboxic (98–90 Ma) conditions with deposition interpreted to have occurred within and beneath an oxygen minimum zone, respectively. In contrast, late Turonian–early Campanian (90–82 Ma) freshening and restricted euxinic basin conditions may signal the start of widespread restriction known to characterize the Paleogene Arctic. Overall, these results highlight that middle Cretaceous Arctic deepwater remained a productive marine carbon sink coupled to the global carbon cycle despite evolving Arctic greenhouse conditions.
ISSN:0012-821X
DOI:10.1016/j.epsl.2024.118948