U-Pb zircon geochronology of dropstones and IRD in the Amundsen Sea, applied to the question of bedrock provenance and Miocene-Pliocene ice sheet extent in West Antarctica

Siddoway, C. S.; Thomson, Stuart N.; Hemming, S. R.; Buchband, Hannah; Quigley, Cade; Furlong, Heather; Hilderman, Robin; Robinson, D.E.; Watkins, Connor; Cox, Stephen E.; Licht, Kathy J.

doi:10.5194/egusphere-egu21-9151

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“…Sand‐sized biogenic components such as foraminifera associated with IRD provided insight into the tidewater glacial cycle in the Gulf of Alaska (Cowan et al., 2020) and the opportunity to develop a high‐resolution chronology for the Antarctica Peninsula drifts (Hillenbrand et al., 2021). In the Antarctic, sediment provenance can be determined by comparing 40 Ar/ 39 Ar ages of hornblende grains and U‐Pb zircon geochronology within the IRD fraction to bedrock geology (Roy et al., 2007; Siddoway et al., 2021). However, the connection between deep sea IRD records and the specific retreat or collapse of the West Antarctic Ice Sheet requires recovery of drill core from areas proximal to the ice sheet (Escutia et al., 2019; Patterson et al., 2022).…”

Section: Commentarymentioning

confidence: 99%

Unraveling the Deep‐Sea Sedimentary Record of Ice Sheet History

Cowan

2022

Paleoceanog and Paleoclimatol

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The deep-sea sedimentary archive holds millions of years of continental ice sheet history in the form of ice-rafted debris or detritus, IRD for short. Sediment laden icebergs float out to sea bearing terrigenous sediments, which melt out of the ice and are deposited in marine sediments, commonly hemipelagic and pelagic silty clay or diatom ooze (Figure 1). IRD collected in marine sediment cores documents the presence of marine ice sheets that expanded across the continental shelves. Accessing and understanding this sedimentary archive has never been more important than today, when marine ice shelves and outlet glaciers are destabilizing due to atmospheric and ocean warming (DeConto et al., 2021;IPCC, 2022). In this sense, past records of ice retreat recorded in deep sea sediment cores provide insight into how ice sheets behaved during past warm climate intervals, which offers a glimpse into future vulnerability of marine ice sheets in Greenland and Antarctica (i.e., Bailey et al., 2022;Weber et al., 2021).Although the concept of IRD seems simple, its identification and measurement within marine sediment is not. Glaciers can incorporate the full range of particle sizes into icebergs, from clay to boulders, quantification of IRD within marine sediment is largely limited to a narrow range of sizes. This size range falls between pebbles on the upper end that can fit into gravity and piston cores, or drill core recovered by the D/V JODIES Resolution (operated by the International Ocean Discovery Program (IODP)) medium-to-coarse sand on the lower end, which is considered too large to have been transported by other marine sedimentary processes. McKay et al. (2022) thoroughly address the efficacy of laboratory methodologies most commonly used to measure IRD abundance in Antarctic cores. Their thorough analysis highlights a topic that has been previously overlooked and has become

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Section: Commentarymentioning

confidence: 99%

Unraveling the Deep‐Sea Sedimentary Record of Ice Sheet History

Cowan

2022

Paleoceanog and Paleoclimatol

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U-Pb zircon geochronology of dropstones and IRD in the Amundsen Sea, applied to the question of bedrock provenance and Miocene-Pliocene ice sheet extent in West Antarctica

Cited by 1 publication

References 0 publications

Unraveling the Deep‐Sea Sedimentary Record of Ice Sheet History

Unraveling the Deep‐Sea Sedimentary Record of Ice Sheet History

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