Subglacial discharge controls seasonal variations in the thermal structure of a glacial lake in Patagonia

Sugiyama, Shin; Minowa, Masahiro; Fukamachi, Yasushi; Hata, Shuntaro; Yamamoto, Yoshihiro; Sauter, Tobias; Schneider, Christoph; Schaefer, Marius

doi:10.1038/s41467-021-26578-0

Cited by 13 publications

(8 citation statements)

References 46 publications

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“…12). These observations are consistent with records from proglacial lakes of other lacustrine glaciers (Boyce and others, 2007;Trüssel and others, 2013;Truffer and Motyka, 2016;Sugiyama andothers, 2019, 2021). Thus, at lacustrine glaciers, subaqueous melt plays a subordinate role.…”

Section: Calvingsupporting

confidence: 90%

Response of lacustrine glacier dynamics to atmospheric forcing in the Cordillera Darwin

Langhamer,

Sauter,

Temme

et al. 2024

J. Glaciol.

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Calving glaciers respond quickly to atmospheric variability through ice dynamic adjustment. Particularly, single weather extremes may cause changes in ice-flow velocity and terminus position. Occasionally, this can lead to substantial event-driven mass loss at the ice front. We examine changes in terminus position, ice-flow velocity, and calving flux at the grounded lacustrine Schiaparelli Glacier in the Cordillera Darwin using geo-referenced time-lapse camera images and remote sensing data (Sentinel-1) from 2015 to 2022. Lake-level records, lake discharge measurements, and a coupled energy and mass balance model provide insight into the subglacial water discharge. We use downscaled reanalysis data (ERA-5) to identify climate extremes and track land-falling atmospheric rivers to investigate the ice-dynamic response on possible atmospheric drivers. Meltwater controls seasonal variations in ice-flow velocity, with an efficient subglacial drainage system developing during the warm season and propagating up-glacier. Calving accounts for 4.2% of the ice loss. Throughout the year, warm spells, wet spells, and landfalling atmospheric rivers promote calving. The progressive thinning of the ice destabilizes the terminus position, highlighting the positive feedback between glacier thinning, near-terminus ice-flow acceleration, and calving flux.

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Section: Calvingsupporting

confidence: 90%

Response of lacustrine glacier dynamics to atmospheric forcing in the Cordillera Darwin

Langhamer,

Sauter,

Temme

et al. 2024

J. Glaciol.

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“…Notably, some progress on determining ice‐marginal lake surface temperatures has recently been made (Dye et al., 2021) but remotely‐sensed surface temperatures are limited, as they do not effectively represent water temperature at depth, or temperature through the water column and associated seasonality (c.f. Sugiyama et al., 2021). The length (and thickness) of a glacier – lake boundary is important for controlling lake evolution.…”

Section: Discussionmentioning

confidence: 99%

Ice‐Marginal Proglacial Lakes Across Greenland: Present Status and a Possible Future

Carrivick

How

Lea

et al. 2022

Geophysical Research Letters

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“…The effect of higher than average wind speeds is also present in the winter, although to a lesser extent. Detailed, basin-wide measurements of lake circulation and suspended sediment concentrations (Sugiyama et al, 2016(Sugiyama et al, , 2021 yield similar information about the drivers of sedimentation across the lake basin.…”

Section: Pxi As a Paleoclimatic Proxymentioning

confidence: 98%

Review of &#8220;Paleoclimatic value of sediment pixel intensity time series from Lago Argentino, Patagonia&#8221;

2022

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Subglacial discharge controls seasonal variations in the thermal structure of a glacial lake in Patagonia

Cited by 13 publications

References 46 publications

Response of lacustrine glacier dynamics to atmospheric forcing in the Cordillera Darwin

Response of lacustrine glacier dynamics to atmospheric forcing in the Cordillera Darwin

Ice‐Marginal Proglacial Lakes Across Greenland: Present Status and a Possible Future

Review of &#8220;Paleoclimatic value of sediment pixel intensity time series from Lago Argentino, Patagonia&#8221;

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Subglacial discharge controls seasonal variations in the thermal structure of a glacial lake in Patagonia

Cited by 13 publications

References 46 publications

Response of lacustrine glacier dynamics to atmospheric forcing in the Cordillera Darwin

Response of lacustrine glacier dynamics to atmospheric forcing in the Cordillera Darwin

Ice‐Marginal Proglacial Lakes Across Greenland: Present Status and a Possible Future

Review of &amp;#8220;Paleoclimatic value of sediment pixel intensity time series from Lago Argentino, Patagonia&amp;#8221;

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Review of “Paleoclimatic value of sediment pixel intensity time series from Lago Argentino, Patagonia”