Maximum Southwest Greenland Ice Sheet Recession in the Early Holocene

Lesnek, Alia J.; Briner, Jason P.; Young, Nicolás E.; Cuzzone, Joshua

doi:10.1029/2019gl083164

Cited by 29 publications

(18 citation statements)

References 104 publications

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“…Briner and colleagues take this approach. The authors show that their estimates for the Holocene are in good agreement with recently published geol ogical reconstructions of Holocene ice-margin positions in WSW Greenland 7 .…”

Section: Andy Aschwandensupporting

confidence: 85%

The worst is yet to come for the Greenland ice sheet

Aschwanden¹

2020

Nature

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Section: Andy Aschwandensupporting

confidence: 85%

The worst is yet to come for the Greenland ice sheet

Aschwanden¹

2020

Nature

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“…Ice sheet model simulations suggest several kilometers of retreat of the 585 southwestern margin of the Greenland Ice Sheet during the middle Holocene (Lecavalier et al, 2014;Simpson et al, 2009;Tarasov & Peltier, 2003). Direct measurements of the western Greenland Ice 587 Sheet margin extent, however, show only minor Holocene retreat, around 1 to 10 kilometers behind the present margin (Håkansson et al, 2014;Lesnek et al, 2020;Ruskeeniemi et al, 2018;Young & Briner, 2015). An ice sheet flow line model matched to tightly constrained Holocene ice sheet margin extents near Kangerlussuaq (Lesnek et al, 2020;Young et al, 2020) shows that winter precipitation may have 591 been 0.2 to 0.4 meters water equivalent (25 to 40%) greater than 20 th century values to offset middle Holocene ablation (Fig.…”

mentioning

confidence: 99%

Reconstructing Arctic Precipitation Seasonality Using Aquatic Leaf Wax δ²H in Lakes With Contrasting Residence Times

Thomas

Hollister

Cluett

et al. 2020

Paleoceanog and Paleoclimatol

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Arctic precipitation is predicted to increase this century. Records of past precipitation seasonality 17 provide baselines for a mechanistic understanding of the dynamics controlling Arctic precipitation. We present an approach to reconstruct Arctic precipitation seasonality using stable hydrogen isotopes (δ 2 H) of aquatic plant waxes in neighboring lakes with contrasting water residence times, and present a case study of this approach in two lakes on western Greenland. Residence time calculations suggest 21 that growing season lake water δ 2 H in one lake reflects summer precipitation δ 2 H, while the other reflects amount-weighted annual precipitation δ 2 H and evaporative enrichment. Aquatic plant wax δ 2 H in the "summer lake" is relatively constant throughout the Holocene, perhaps reflecting competing 24 effects of local summer warmth and increased distal moisture transport due to a strengthened latitudinal temperature gradient. In contrast, aquatic plant wax δ 2 H in the "mean annual lake" is 100‰ 2 H-depleted from 6 to 4 ka relative to the beginning and end of the record. Because there are relatively 27 minor changes in summer precipitation δ 2 H, we interpret the 100‰ 2 H-depletion in mean annual precipitation to reflect an increase in winter precipitation amount, likely accompanied by changes in winter precipitation δ 2 H and decreased evaporative enrichment. Thus, unlike the "summer lake," the "mean-annual lake" records changes in winter precipitation. This dual-lake approach may be applied to 31 reconstruct past changes in precipitation seasonality at sites with strong precipitation isotope seasonality and minimal lake water evaporative enrichment.

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“…Because the outer flanks of western GrIS contain numerous deep and steep-sided subglacial troughs, we focus our investigation on a single flowline transect so that we can employ high time/space resolution in our model. Our transient model includes higher order stresses, a well-informed paleoclimate (Buizert and others, 2018; Downs and others, 2020), thermally active bedrock, and honors previously published records of terminus retreat (Briner and others, 2016; Lesnek and others, 2020; Young and others, 2020). We track the constitutive components of the basal heat budget during the transient simulation to isolate the energy sources and sinks associated with the migration of frozen/melted bed conditions.…”

Section: Introductionmentioning

confidence: 87%

“…Detailed chronologies of Holocene ice margin retreat have been established for this sector of the ice sheet based on glacial geologic evidence with 10 Be and 14 C age dating (Briner and others, 2016; Lesnek and others, 2020; Young and others, 2020). The ice margin retreated most rapidly during the first half of the last 11 ka.…”

Section: Methodsmentioning

confidence: 99%

Millennial-scale migration of the frozen/melted basal boundary, western Greenland ice sheet

et al. 2022

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The geometry and thermal structure of western Greenland ice sheet are known to have undergone relatively substantial change over the Holocene. Evolution of the frozen and melted fractions of the bed associated with the ice-sheet retreat over this time frame remains unclear. We address this question using a thermo-mechanically coupled flowline model to simulate a 11 ka period of ice-sheet retreat in west central Greenland. Results indicate an episode of ~100 km of terminus retreat corresponded to ~16 km of upstream frozen/melted basal boundary migration. The majority of migration of the frozen area is associated with the enhancement of the frictional and strain heating fields, which are accentuated toward the retreating ice margin. The thermally active bedrock layer acts as a heat sink, tending to slow contraction of frozen-bed conditions. Since the bedrock heat flux in our region is relatively low compared to other regions of the ice sheet, the frozen region is relatively greater and therefore more susceptible to marginward changes in the frictional and strain heating fields. Migration of melted regions thus depends on both geometric changes and the antecedent thermal state of the bedrock and ice, both of which vary considerably around the ice sheet.

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Maximum Southwest Greenland Ice Sheet Recession in the Early Holocene

Cited by 29 publications

References 104 publications

The worst is yet to come for the Greenland ice sheet

The worst is yet to come for the Greenland ice sheet

Reconstructing Arctic Precipitation Seasonality Using Aquatic Leaf Wax δ²H in Lakes With Contrasting Residence Times

Millennial-scale migration of the frozen/melted basal boundary, western Greenland ice sheet

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Maximum Southwest Greenland Ice Sheet Recession in the Early Holocene

Cited by 29 publications

References 104 publications

The worst is yet to come for the Greenland ice sheet

The worst is yet to come for the Greenland ice sheet

Reconstructing Arctic Precipitation Seasonality Using Aquatic Leaf Wax δ2H in Lakes With Contrasting Residence Times

Millennial-scale migration of the frozen/melted basal boundary, western Greenland ice sheet

Contact Info

Product

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Reconstructing Arctic Precipitation Seasonality Using Aquatic Leaf Wax δ²H in Lakes With Contrasting Residence Times