High Arctic Holocene temperature record from the Agassiz ice cap and Greenland ice sheet evolution

Lecavalier, Benoit; Fisher, David; Milne, Glenn A.; Vinther, Bo M.; Tarasov, Lev; Huybrechts, Philippe; Lacelle, Denis; Main, Brittany; Zheng, James; Bourgeois, J.; Dyke, Arthur S.

doi:10.1073/pnas.1616287114

Cited by 185 publications

(223 citation statements)

References 31 publications

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“…The GISP2 melt layers suggest a summer thermal maximum from roughly 9-6 ka BP, shorter in duration than, but overlapping in time with, the broad HTM that we find in Greenland SAT between 10 and 6 ka BP (Figure 2d). Recently, Lecavalier et al (2017) suggested that the timing of the HTM is earlier (11-10 ka BP) on Ellesmere Island, based on elevation-corrected records of summer melt and water isotopes-at that same location our merged product suggests maximum HTM warmth to occur around 9.5 ka BP (Figure 2h). Recently, Lecavalier et al (2017) suggested that the timing of the HTM is earlier (11-10 ka BP) on Ellesmere Island, based on elevation-corrected records of summer melt and water isotopes-at that same location our merged product suggests maximum HTM warmth to occur around 9.5 ka BP (Figure 2h).…”

Section: Evaluating the Gis Surface Temperature Fieldssupporting

confidence: 52%

“…(b) TraCE-21Ka simulated AMOC strength (gray) and AMOC strength required to bring TraCE-21 K simulations and ice core reconstructions into agreement (orange). (h) Ellesmere Island temperature reconstruction (red curve) by Lecavalier et al (2017) and our merged product (gray curve) at that site. Horizontal bars denote data averages during the Last Glacial Maximum (22-18 ka BP) and "stable" part of the Holocene (10-0 ka BP).…”

Section: Temperature Seasonality Of Climate Forcingsmentioning

confidence: 99%

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Greenland‐Wide Seasonal Temperatures During the Last Deglaciation

Buizert

Keisling

Box

et al. 2018

Geophysical Research Letters

147

209

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The sensitivity of the Greenland ice sheet to climate forcing is of key importance in assessing its contribution to past and future sea level rise. Surface mass loss occurs during summer, and accounting for temperature seasonality is critical in simulating ice sheet evolution and in interpreting glacial landforms and chronologies. Ice core records constrain the timing and magnitude of climate change but are largely limited to annual mean estimates from the ice sheet interior. Here we merge ice core reconstructions with transient climate model simulations to generate Greenland‐wide and seasonally resolved surface air temperature fields during the last deglaciation. Greenland summer temperatures peak in the early Holocene, consistent with records of ice core melt layers. We perform deglacial Greenland ice sheet model simulations to demonstrate that accounting for realistic temperature seasonality decreases simulated glacial ice volume, expedites the deglacial margin retreat, mutes the impact of abrupt climate warming, and gives rise to a clear Holocene ice volume minimum.

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Section: Evaluating the Gis Surface Temperature Fieldssupporting

confidence: 52%

Section: Temperature Seasonality Of Climate Forcingsmentioning

confidence: 99%

Greenland‐Wide Seasonal Temperatures During the Last Deglaciation

Buizert

Keisling

Box

et al. 2018

Geophysical Research Letters

147

209

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“…The resulting GrIS isostatic adjustment is therefore the combination of these local and non-local responses which make the GIA treatment rather complex. In principle, these nonlocal effects should be taken into account as they contribute to the sea-level variability, becoming especially relevant at the beginning of deglaciations when the ice mass loss is significantly induced by sea-level rise (Lecavalier et al, 2017). However, for the sake of simplicity, the GrIS isostatic adjustment is assumed here to be only due to local ice mass variations, as other works have done in the past (Greve and Blatter, 2009;Helsen et al, 2013;Huybrechts, 2002;Langebroek and Nisancioglu, 2016;Stone et al, 2013).…”

Section: Discussionmentioning

confidence: 99%

The sensitivity of the Greenland Ice Sheet to glacial–interglacial oceanic forcing

et al. 2018

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Abstract.Observations suggest that during the last decades the Greenland Ice Sheet (GrIS) has experienced a gradually accelerating mass loss, in part due to the observed speedup of several of Greenland's marine-terminating glaciers. Recent studies directly attribute this to warming North Atlantic temperatures, which have triggered melting of the outlet glaciers of the GrIS, grounding-line retreat and enhanced ice discharge into the ocean, contributing to an acceleration of sea-level rise. Reconstructions suggest that the influence of the ocean has been of primary importance in the past as well. This was the case not only in interglacial periods, when warmer climates led to a rapid retreat of the GrIS to land above sea level, but also in glacial periods, when the GrIS expanded as far as the continental shelf break and was thus more directly exposed to oceanic changes. However, the GrIS response to palaeo-oceanic variations has yet to be investigated in detail from a mechanistic modelling perspective. In this work, the evolution of the GrIS over the past two glacial cycles is studied using a three-dimensional hybrid ice-sheetshelf model. We assess the effect of the variation of oceanic temperatures on the GrIS evolution on glacial-interglacial timescales through changes in submarine melting. The results show a very high sensitivity of the GrIS to changing oceanic conditions. Oceanic forcing is found to be a primary driver of GrIS expansion in glacial times and of retreat in interglacial periods. If switched off, palaeo-atmospheric variations alone are not able to yield a reliable glacial configuration of the GrIS. This work therefore suggests that considering the ocean as an active forcing should become standard practice in palaeo-ice-sheet modelling.

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“…The retreat history of the GrIS during the last deglaciation was reconstructed using an ice sheet model constrained with evidence of past margin positions and relative sea-level indicators [103,112]. The reconstruction provides important constraints for model spin-up to the present day, when representing the correct loading history and isostatic response.…”

Section: Paleo Ice Sheet Simulationsmentioning

confidence: 99%

Recent Progress in Greenland Ice Sheet Modelling

Goelzer

Robinson

Seroussi

et al. 2017

Curr Clim Change Rep

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Purpose of Review This paper reviews the recent literature on numerical modelling of the dynamics of the Greenland ice sheet with the goal of providing an overview of advancements and to highlight important directions of future research. In particular, the review is focused on large-scale modelling of the ice sheet, including future projections, model parameterisations, paleo applications and coupling with models of other components of the Earth system. Recent Findings Data assimilation techniques have been used to improve the reliability of model simulations of the Greenland ice sheet dynamics, including more accurate initial states, more comprehensive use of remote sensing as well as paleo observations and inclusion of additional physical processes. Summary Modellers now leverage the increasing number of high-resolution satellite and air-borne data products to initialise ice sheet models for centennial time-scale simulations, needed for policy relevant sea-level projections. Modelling long-term past and future ice sheet evolution, which requires simplified but adequate representations of the interactions with the other components of the Earth system, has seen a steady improvement. Important developments are underway to include ice sheets in climate models that may lead to routine simulation of the fully coupled Greenland ice sheet-climate system in the coming years.

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High Arctic Holocene temperature record from the Agassiz ice cap and Greenland ice sheet evolution

Cited by 185 publications

References 31 publications

Greenland‐Wide Seasonal Temperatures During the Last Deglaciation

Greenland‐Wide Seasonal Temperatures During the Last Deglaciation

The sensitivity of the Greenland Ice Sheet to glacial–interglacial oceanic forcing

Recent Progress in Greenland Ice Sheet Modelling

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