Antarctic ice-sheet sensitivity to obliquity forcing enhanced through ocean connections

Levy, R. H.; Meyers, Stephen R.; Naish, T.; Golledge, Nicholas R.; McKay, Robert; Crampton, James S.; DeConto, Robert M.; Santis, Laura De; Florindo, Fabio; Gasson, E.; Harwood, David M.; Luyendyk, Bruce P.; Powell, Ross D.; Clowes, Christopher D.; Kulhanek, Denise K.

doi:10.1038/s41561-018-0284-4

Cited by 103 publications

(170 citation statements)

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“…These ice‐proximal records suggest that the ice sheet was principally extending into the marine realm during this interval and was at some points marine‐grounded. Benthic δ 18 O records have low sensitivity to obliquity forcing during this time interval (Levy et al, ). Subsequently, the warmer average North Atlantic temperatures between 24.5 and 21 Ma correspond with Ross Sea sedimentation dominated by nonglacially deposited sandstones and mudstones, interpreted as period when the ice sheet was predominantly land‐based.…”

Section: Discussionmentioning

confidence: 99%

“…A large variation in benthic δ 18 O, in the absence of appreciable midlatitude SST change, could reflect appreciable (>3‐fold) polar amplification of SST change in deep‐water formation areas if ice volume were constant, and/or ice volume as a significant component of benthic δ 18 O. This period is marked by low sensitivity of megasplice benthic δ 18 O to obliquity forcing (Figure b), which is interpreted to reflect a state when ice sheets responded to direct insolation forcing rather than regional temperature (Levy et al, ). At the same time, the amplitude of benthic δ 18 O on short eccentricity timescale was also low (Liebrand et al, ).…”

Section: Discussionmentioning

confidence: 99%

“…(a) Sea surface temperature from Site 1406A and its 16th and 84th confidence intervals. (b) Obliquity sensitivity (Levy et al, ) from obliquity forcing variance of benthic δ 18 O. (c) The blue line shows Antarctic proximal environmental motifs from Levy et al () for the middle Miocene from ANDRILL cores; the black lines show disconformities.…”

Section: Discussionmentioning

confidence: 99%

“…In the ~1 Myr prior to and following the O/M boundary (from 24.5 to 22 Ma)—an interval encompassing both warmer temperatures and lower average benthic δ 18 O than the preceding Oligocene—the larger amplitude (5°C) variation in midlatitude SST is coupled to a 1‰ range in benthic δ 18 O, with the warmest temperatures coinciding with minima in benthic δ 18 O. The Oligocene Miocene transitionitself is marked by a two‐step decrease in North Atlantic SST, analogous to the two‐step rise in high resolution benthic δ 18 O in orbitally resolved records (Liebrand et al, ; Mawbey & Lear, ), the pacing of which has been recently suggested to be driven by both changes in atmospheric carbon dioxide and obliquity (Greenop et al, ; Levy et al, ). Across the O/M boundary, previous high‐resolution analysis of a tropical Atlantic site between 22.4 to 23.7 Ma showed that intervals of increased δ 18 O sw interpreted as recording ice growth were coupled to intervals of bottom water cooling, inferred from benthic foraminiferal Mg/Ca (Mawbey & Lear, ).…”

Section: Discussionmentioning

confidence: 99%

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Midlatitude Temperature Variations in the Oligocene to Early Miocene

Guitián

Phelps

Polissar

et al. 2019

Paleoceanog and Paleoclimatol

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Antarctic ice sheet margin extent and the sensitivity of benthic δ18O to orbital forcing have varied on million‐year timescales during the Oligocene to Early Miocene. However, few sea surface temperature (SST) records for this time interval exist to evaluate links between polar processes and mean temperature outside polar regions. Here, we present a new record of SST for the time interval 30 to 17 Ma derived from the long‐chain alkenone unsaturation ratio ( U37k′) at Integrated Ocean Drilling Program Site 1406A in the midlatitude North Atlantic. Results confirm that warm temperatures from 24°C to over 30°C prevailed in midlatitudes in this time and suggest a transition from colder early‐middle Oligocene to warmer average conditions after 24.5 Ma. The global significance of this transition is highlighted by the coincidence with changes in the dominance from marine‐ to terrestrial‐terminating ice sheets in the Ross Sea around Antarctica. The longest continuous section of the record (20.6 to 26.6 Ma) contains multiple 2 million‐year cycles in SST, potentially paced by long obliquity modulation. Complex and temporally varying relationships are observed between North Atlantic SST and benthic δ18O in paired samples; significant covariation is only observed around the Oligocene‐Miocene transition, coincident with a lower average marine ice extent. These North Atlantic U37k′ temperature records provide a new context in which to examine the stability of climate and the Antarctic ice sheet during the Oligocene and early Miocene.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

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Midlatitude Temperature Variations in the Oligocene to Early Miocene

Guitián

Phelps

Polissar

et al. 2019

Paleoceanog and Paleoclimatol

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“…Previous studies suggest links with orbital cycles during the Plio–Pleistocene (Naish et al ., ; Patterson et al ., ), whereas early to middle Miocene glacial cycles may be driven by a combination of orbital cycles and complex carbon‐cycle feedbacks (Gasson et al ., ; Levy et al ., ). The dominant late Miocene Antarctic climate driver is thought to be obliquity (Levy et al ., ), however the sedimentary record remains fragmented. This study may provide a few insights: (i) glacial sequences are likely to represent very short time intervals, but some may be linked to obliquity cycles within their respective interpreted polarity reversal zones (Fig.…”

Section: Discussionmentioning

confidence: 99%

Glacial sequence stratigraphy of ANDRILL‐1B core reveals a dynamic subpolar Antarctic Ice Sheet in Ross Sea during the late Miocene

Rosenblume

Powell

2019

Sedimentology

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The Upper Miocene interval of the AND‐1B sediment core is a muddy ca 300 m thick succession of glacimarine strata that was recovered from the McMurdo sector of the Ross Ice Shelf, Antarctica. This succession comprises lithofacies consistent with those formed in modern polythermal glacial systems with large volumes of subglacial meltwater. In particular, meltwater‐associated facies and iceberg‐rafted debris suggest that these late Miocene glacial systems were similar to subpolar glaciers like those in Svalbard today. Modern subpolar systems in Svalbard accumulate sediments at rates of ca 50 to 100 mm a−1 within ca 1 km of their grounded tidewater cliffs in waters up to hundreds of metres deep. Here, the rifted tectonic setting and glacio‐isostatic load of the Antarctic Ice Sheet enhanced accommodation for this succession. Based on these interpretations, the glacial sequence stratigraphic model of Powell & Cooper (2002) is applied to the study interval in an effort to better understand ice dynamics during this time. Base level is defined as the grounding line (where the ice sheet is grounded on the sea floor) and the surface that projects basinward (a correlative conformity). Glacial sequence stratigraphic description of the sediment core reveals 10 glacial sequences bounded by glacial erosion surfaces and two lower‐ranked glacial sequences bounded by correlative conformities. These glacial sequences occur in regular fining‐upward stratigraphic patterns and consist of two distinct styles of glacial retreat: packages with grounding‐line fan deposits and those without them. Lastly, in an effort to fill the gap between the middle Miocene and Plio‐Pleistocene climate histories of Antarctica, comparison of the AND‐1B Upper Miocene interval with the obliquity curve reveals one glacial–interglacial cycle and identifies erosion surfaces along which significant time may be missing.

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The Monterey Event and the Paleocene‐Eocene Thermal Maximum

Babila

Foster

2021

Large Igneous Provinces

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The Columbia River Flood Basalts and the North Atlantic Igneous Province are two of the youngest Large Igneous Provinces (LIPs) and both are associated with perturbations of the global carbon-cycle. Here we explore the link between the emplacement and eruption of LIPs and their associated carbon-cycle and climatic responses. The emplacement of both LIPs are associated with two well-known climate events: the Monterey Carbon Isotope Excursion (MCIE; ~17-13.5 Ma) and the Paleocene-Eocene Thermal Maximum (PETM; ~56 Ma) characterized by a positive 1‰ and negative 3-5‰ carbon isotope excursion, respectively. Both are also associated with signifi cant global warming. However, despite these contrasting timescales and carbon isotope trends, boron-based proxy records indicate a similar surface ocean carbonate system response. In both cases, elevated LIP derived carbon dioxide emissions led to oceanic absorption of the carbon released causing a decline of surface ocean pH and an increase in dissolved inorganic carbon. We conclude that, although similar underlying carbon-cycle processes are at play during both events, their specific behavior is somewhat different as the magnitude, carbon emissions rate (slow vs. fast), and background climate state (icehouse vs. greenhouse) conspire to cause distinct carbon isotope expressions in the sedimentary record and variable climatic responses to each LIP emplacement.

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Antarctic ice-sheet sensitivity to obliquity forcing enhanced through ocean connections

Cited by 103 publications

References 46 publications

Midlatitude Temperature Variations in the Oligocene to Early Miocene

Midlatitude Temperature Variations in the Oligocene to Early Miocene

Glacial sequence stratigraphy of ANDRILL‐1B core reveals a dynamic subpolar Antarctic Ice Sheet in Ross Sea during the late Miocene

The Monterey Event and the Paleocene‐Eocene Thermal Maximum

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