Simulating the Last Interglacial Greenland stable water isotope peak: The role of Arctic sea ice changes

Malmierca‐Vallet, Irene; Sime, Louise; Tindall, Julia; Capron, Émilie; Valdes, Paul J.; Vinther, Bo M.; Holloway, Max

doi:10.1016/j.quascirev.2018.07.027

Cited by 24 publications

(36 citation statements)

References 71 publications

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“…A1 and Table A1). We follow the methodology of Holloway et al (2016Holloway et al ( , 2017 and Malmierca-Vallet et al (2018) on sea ice forcing. This set of simulations help us explore both changes in the extent (land-ice fraction) and elevation of the GIS.…”

Section: Methodsmentioning

confidence: 99%

“…The different behaviour found at Camp Century site is likely linked to the reduced winter sea ice concentration over the Baffin Bay on both decreased and increased elevation change scenarios ( Fig. 3 d and f); reduced sea ice concentration permits more moisture to penetrate inland Greenland (Malmierca-Vallet et al, 2018;Sime et al, 2013).…”

Section: Changes In Precipitation Patternmentioning

confidence: 99%

“…We use the sea ice retreat simulations of Malmierca-Vallet et al (2018) to isolate the impacts of δ 18 O due to sea ice variation.…”

mentioning

confidence: 99%

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Sea-ice feedbacks influence the isotopic signature of Greenland Ice Sheet elevation changes: Last Interglacial HadCM3 simulations

Malmierca‐Vallet¹,

Sime²,

Valdes³

et al. 2020

Preprint

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Abstract. Changes in the Greenland ice sheet (GIS) affect global sea level. Greenland stable water isotope (δ18O) records from ice cores offer information on past changes in the surface of the GIS. Here, we use the isotope-enabled HadCM3 climate model to simulate a set of Last Interglacial (LIG) idealised GIS surface elevation change scenarios focusing on GIS ice core sites. We investigate how δ18O depends on the magnitude and sign of GIS elevation change and evaluate how the response is altered by sea ice changes. We find that modifying GIS elevation induces changes in Northern Hemisphere atmospheric circulation, sea ice and precipitation patterns. These climate feedbacks lead to ice core-averaged isotopic lapse rates of 0.49 ‰ per 100 m for the lowered GIS states and 0.29 ‰ per 100 m for the enlarged GIS states. This is lower than the spatially derived Greenland lapse rates of 0.62–0.72 ‰ per 100 m. These results thus suggest non-linearities in the isotope-elevation relationship, and have consequences for the interpretation of past elevation and climate changes across Greenland. In particular, our results suggest that winter sea ice changes may significantly influence isotopic-elevation gradients: winter sea ice effect can decrease (increase) modelled core-averaged isotopic lapse rate values by about -19 % (and +28 %) for the lowered (enlarged) GIS states respectively. The largest influence of sea ice on δ18O changes is found in coastal regions like the Camp Century site.

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Section: Methodsmentioning

confidence: 99%

Section: Changes In Precipitation Patternmentioning

confidence: 99%

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Sea-ice feedbacks influence the isotopic signature of Greenland Ice Sheet elevation changes: Last Interglacial HadCM3 simulations

Malmierca‐Vallet¹,

Sime²,

Valdes³

et al. 2020

Preprint

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“…Stronger LIG spring and summertime insolation contributed to this warmth, as well as feedbacks amplifying the initial insolation signal, in particular feedbacks related to the 25 marine and land cryosphere. Previous climate model simulations of the LIG, forced by appropriate greenhouse gas (GHG) and orbital changes, have failed to capture the observed high temperatures at higher latitudes (Malmierca-Vallet et al, 2018;Masson-Delmotte et al, 2011;Otto-Bliesner et al, 2013;Lunt et al, 2013). Models used during the previous Coupled Model Intercomparison Project 5 (CMIP5) disagree on the magnitude of Arctic sea ice retreat during the LIG: the diversity of sea ice behaviour across models was linked to the spread in simulated surface temperatures and in the magnitude of the polar 30 amplification (Otto-Bliesner et al, 2013;Lunt et al, 2013;IPCC, 2013).…”

Section: Introductionmentioning

confidence: 99%

“…40 Alongside a previous lack of a common experimental protocol, our ability to evalutate CMIP models has previously been hindered by difficulties in determining LIG sea ice extent from marine core evidence (e.g. Otto-Bliesner et al, 2013;Sime et al, 2013;Malmierca-Vallet et al, 2018;Stein et al, 2017). Planktonic foraminifers representative of subpolar, seasonally open waters lived in the central part of the Arctic Ocean.…”

Section: Introductionmentioning

confidence: 99%

A multi-model CMIP6 study of Arctic sea ice at 127 ka: Sea ice data compilation and model differences

Sime¹,

Kageyama²,

Sicard³

et al. 2020

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The Last interglacial (LIG) is a period with increased summer insolation at high northern latitudes, which results in strong changes in the terrestrial and marine cryosphere. Understanding the mechanisms for this response via climate modelling and comparing the models' representation of climate reconstructions is one of the objectives set up by the Paleoclimate Modelling Intercomparison Project for its contribution to the sixth phase of the Coupled Model Intercomparison Project. Here we analyse the results from 12 climate models in terms of Arctic sea ice. The mean pre-industrial to LIG reduction in minimum 5 sea ice area (SIA) reaches 59% (multi-model mean LIG area is 2.21 mill. km 2 , compared to 5.85 mill. km 2 for the PI), and the range of model results for LIG minimum sea ice area (from 0.02 to 5.65 mill. km 2 ) is larger than for PI (from 4.10 to 8.30 mill.km 2 ). On the other hand there is little change for the maximum sea ice area (which is 12 mill. km 2 for both the PI and the LIG, with a standard deviation of 1.04 mill. km 2 for PI and 1.21 mill. km 2 for LIG). To evaluate the model results we synthesize LIG sea ice data from marine cores collected in the Arctic Ocean, Nordic Seas and northern North Atlantic. South of 78 • N in 10 the Atlantic and Nordic seas the LIG was seasonally ice-free. North of 78 • N there are some discrepancies between sea-ice reconstructions based on dinocysts/foraminifers/ostracods and IP25: some sites have both seasonal and perennial interpretations based on the same core, but different indicators. Because of the conflicting interpretations it is not possible for any one model to match every data point in our data synthesis, or say whether the Arctic was seasonally ice-free. Drivers for the inter-model differences are: different phasing of the up and down short-wave anomalies over the Arctic ocean, associated with differences 15 in model albedo; possible cloud property differences, in terms of optical depth; LIG ocean circulation changes which occur for some, but not all, LIG simulations. Finally we note that inter-comparisons between the LIG simulations, and simulations with moderate CO2 increase (during the transition to high CO2 levels), may yield insight into likely 21C Arctic sea ice changes using these LIG simulations.from boreholes on the Beaufort Sea Shelf seem to likewise support this idea; these indicate that more saline Atlantic water was present on the Beaufort Shelf, suggesting a lack of perennial Arctic sea ice during some part of the LIG (Brigham-Grette and Hopkins, 1995). Ostracodes from the Lomonosov and Mendeleyev Ridges and Morris Jesup Rise suggest minimum sea ice cover during the peak of the LIG (Cronin et al., 2010). Together this set of observations suggests an ice-free (summer sea ice free) Arctic during some part of the LIG. On the other hand, a reconstruction of LIG Arctic sea ice changes made 50 by combining terrestrial and open-water phytoplankton biomarkers with the sea ice proxy IP25 (a carbon-25 highly-branched isoprenoid lipid) suggest that whi...

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Ice Cores and Emulation: Learning More About Past Ice Sheet Shapes

Turner

Wilkinson

Buck

et al. 2019

Springer Proceedings in Mathematics &Amp; Statistics

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Understanding the effect warming has on ice sheets is vital for accurate projections of climate change. A better understanding of how the Antarctic ice sheets have changed size and shape in the past would allow us to improve our predictions of how they may adapt in the future; this is of particular relevance in predicting future global seaCollection of ice sheet reconstructions Z ∈ R 47×5 set of z i values used to make orographies included in HadCM3 simulations

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Simulating the Last Interglacial Greenland stable water isotope peak: The role of Arctic sea ice changes

Cited by 24 publications

References 71 publications

Sea-ice feedbacks influence the isotopic signature of Greenland Ice Sheet elevation changes: Last Interglacial HadCM3 simulations

Sea-ice feedbacks influence the isotopic signature of Greenland Ice Sheet elevation changes: Last Interglacial HadCM3 simulations

A multi-model CMIP6 study of Arctic sea ice at 127 ka: Sea ice data compilation and model differences

Ice Cores and Emulation: Learning More About Past Ice Sheet Shapes

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