Advection and non-climate impacts on the South Pole Ice Core

The South Pole Ice Core (SPICEcore), which spans the past 54 300 years, was drilled far from an ice divide such that ice recovered at depth originated upstream of the core site. If the climate is different upstream, the climate history recovered from the core will be a combination of the upstream co...

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Bibliographic Details
Published in:Climate of the Past
Main Authors: T. J. Fudge, D. A. Lilien, M. Koutnik, H. Conway, C. M. Stevens, E. D. Waddington, E. J. Steig, A. J. Schauer, N. Holschuh
Format: Article in Journal/Newspaper
Language:English
Published: Copernicus Publications 2020
Subjects:
Online Access:https://doi.org/10.5194/cp-16-819-2020
https://doaj.org/article/aecd5929b4264dd0b74b71bdd446af36
Description
Summary:The South Pole Ice Core (SPICEcore), which spans the past 54 300 years, was drilled far from an ice divide such that ice recovered at depth originated upstream of the core site. If the climate is different upstream, the climate history recovered from the core will be a combination of the upstream conditions advected to the core site and temporal changes. Here, we evaluate the impact of ice advection on two fundamental records from SPICEcore: accumulation rate and water isotopes. We determined past locations of ice deposition based on GPS measurements of the modern velocity field spanning 100 km upstream, where ice of ∼20 ka age would likely have originated. Beyond 100 km, there are no velocity measurements, but ice likely originates from Titan Dome, an additional 90 km distant. Shallow radar measurements extending 100 km upstream from the core site reveal large ( ∼20 %) variations in accumulation but no significant trend. Water isotope ratios, measured at 12.5 km intervals for the first 100 km of the flowline, show a decrease with elevation of −0.008 ‰ m −1 for δ 18 O . Advection adds approximately 1 ‰ for δ 18 O to the Last Glacial Maximum (LGM)-to-modern change. We also use an existing ensemble of continental ice-sheet model runs to assess the ice-sheet elevation change through time. The magnitude of elevation change is likely small and the sign uncertain. Assuming a lapse rate of 10 ∘ C km −1 of elevation, the inference of LGM-to-modern temperature change is ∼1.4 ∘ C smaller than if the flow from upstream is not considered.