Geothermal heat flux from measured temperature profiles in deep ice boreholes in Antarctica

Тalalay, Pavel G.; Li, Yazhou; Augustin, Laurent; Clow, Gary D.; Hong, Jialin; Lefebvre, E.; Марков, А. Н.; Motoyama, Hideaki; Ritz, Catherine

doi:10.5194/tc-14-4021-2020

Cited by 22 publications

(26 citation statements)

References 98 publications

(117 reference statements)

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“…Based on the individual GHF datasets, their modelling reveals it to be likely that the ice base has reached the pressure melting point at least once over the last 1.5 million years. Moreover, it has been shown that measured GHF in eastern DML is locally much higher than predicted by geophysical methods (Talalay et al, 2020), consistent with evidence for temperate bed conditions from the recovery of refrozen subglacial water at the EPICA-DML drill site (Weikusat et al, 2017;Wilhelms et al, 2014 conditions affect processes at the glacier bed under slow flow velocities and near the ice divides. In view of the apparent preservation of fluvial landscapes in the basin, it can be suggested that erosion in such settings may be limited to subglacial fluvial action with relatively limited consequences for landscapes.…”

Section: Basal Thermal Regimesupporting

confidence: 74%

Preserved landscapes underneath the Antarctic Ice Sheet reveal the geomorphological history of Jutulstraumen Basin

Franke

Eisermann

Jokat

et al. 2021

Earth Surf Processes Landf

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The landscape of Antarctica, hidden beneath kilometre-thick ice in most places, has been shaped by the interactions between tectonic and erosional processes. The flow dynamics of the thick ice cover deepened pre-formed topographic depressions by glacial erosion, but also preserved the subglacial landscapes in regions with moderate to slow ice flow. Mapping the spatial variability of these structures provides the basis for reconstruction of the evolution of subglacial morphology. This study focuses on the Jutulstraumen Glacier drainage system in Dronning Maud Land, East Antarctica.The Jutulstraumen Glacier reaches the ocean via the Jutulstraumen Graben, which is the only significant passage for draining the East Antarctic Ice Sheet through the western part of the Dronning Maud Land mountain chain. We acquired new bed topography data during an airborne radar campaign in the region upstream of the Jutulstraumen Graben to characterise the source area of the glacier. The new data show a deep relief to be generally under-represented in available bed topography compilations. Our analysis of the bed topography, valley characteristics and bed roughness leads to the conclusion that much more of the alpine landscape that would have formed prior to the Antarctic Ice Sheet is preserved than previously anticipated.We identify an active and deeply eroded U-shaped valley network next to largely preserved passive fluvial and glacial modified landscapes. Based on the landscape classification, we reconstruct the temporal sequence by which ice flow modified the topography since the beginning of the glaciation of Antarctica.

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Section: Basal Thermal Regimesupporting

confidence: 74%

Preserved landscapes underneath the Antarctic Ice Sheet reveal the geomorphological history of Jutulstraumen Basin

Franke

Eisermann

Jokat

et al. 2021

Earth Surf Processes Landf

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“…Talos Dome is near the coast and its climate is tempered by the ocean. When considering the same depth, ice temperature at Talos Dome is about 15-20°C warmer than at inner sites (Talalay et al, 2020).…”

Section: Englacial Weathering Of Dustmentioning

confidence: 89%

Deep ice as a geochemical reactor: insights from iron speciation and mineralogy of dust in the Talos Dome ice core (East Antarctica)

Baccolo

Delmonte

Stefano

et al. 2021

Preprint

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Abstract. Thanks to its insolubility, mineral dust is considered a stable proxy in polar ice cores. With this study we show that below an ice-depth of 1000 m, the Talos Dome ice core (Ross Sea sector of East Antarctica) presents evident and progressive signs of post-depositional processes affecting the mineral dust records. We applied a suite of established and cutting edge techniques to investigate the properties of dust present in the Talos Dome ice core, ranging from concentration and grain-size to elemental-composition and Fe-mineralogy. Results show that through acidic/oxidative weathering, the conditions of deep ice at Talos Dome promote the dissolution of specific minerals and the englacial formation of others, deeply affecting dust primitive features. The expulsion of acidic atmospheric species from ice-grains and their concentration in localized environments is likely the main process responsible for englacial reactions and is related with ice re-crystallization. Deep ice can be seen as a "geochemical reactor" capable of fostering complex reactions which involve both soluble and insoluble impurities. Fe-bearing minerals can efficiently be used to explore such transformations.

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“…Geothermal heat flux is uncertain for most parts of the Antarctic ice sheet, and regional differences between published datasets (Fig. 8) can be substantial (Burton-Johnson et al, 2020;Talalay et al, 2020). Local basal melting occurs under forcing with the Shapiro and Ritzwoller (2004) dataset as well but is largely limited to 0-1 mm a −1 and lies between 0.25-0.5 mm a −1 around EDC.…”

Section: Impact Of Lower Boundary Conditions On Simulated Isochrone Elevation (Iii)mentioning

confidence: 97%

“…Even a near-perfect match to present-day observables can conceal overfitting of the model due to weakly constrained boundary conditions, e.g. uncertainties in the climate forcing or geothermal heat flux (Burton-Johnson et al, 2020;Talalay et al, 2020). To counter the effects of overfitting, promising attempts to improve the initialisation of ice-sheet models have been made which involve transient inversions of multiple surface elevation observations over time (Goldberg et al, 2015), albeit only on the regional scale and limited to the extent of the satellite record.…”

Section: Introductionmentioning

confidence: 99%

Investigating the internal structure of the Antarctic ice sheet: the utility of isochrones for spatiotemporal ice-sheet model calibration

2021

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Abstract. Ice-sheet models are a powerful tool to project the evolution of the Greenland and Antarctic ice sheets and thus their future contribution to global sea-level changes. Testing the ability of ice-sheet models to reproduce the ongoing and past evolution of the ice cover in Greenland and Antarctica is a fundamental part of every modelling effort. However, benchmarking ice-sheet model results against real-world observations is a non-trivial process as observational data come with spatiotemporal gaps in coverage. Here, we present a new approach to assess the accuracy of ice-sheet models which makes use of the internal layering of the Antarctic ice sheet. We calculate isochrone elevations from simulated Antarctic geometries and velocities via passive Lagrangian tracers, highlighting that a good fit of the model to two-dimensional datasets such as surface velocity and ice thickness does not guarantee a good match against the 3D architecture of the ice sheet and thus correct evolution over time. We show that palaeoclimate forcing schemes derived from ice-core records and climate models commonly used to drive ice-sheet models work well to constrain the 3D structure of ice flow and age in the interior of the East Antarctic ice sheet and especially along ice divides but fail towards the ice-sheet margin. The comparison to isochronal horizons attempted here reveals that simple heuristics of basal drag can lead to an overestimation of the vertical interior ice-sheet flow especially over subglacial basins. Our model observation intercomparison approach opens a new avenue for the improvement and tuning of current ice-sheet models via a more rigid constraint on model parameterisations and climate forcing, which will benefit model-based estimates of future and past ice-sheet changes.

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Geothermal heat flux from measured temperature profiles in deep ice boreholes in Antarctica

Cited by 22 publications

References 98 publications

Preserved landscapes underneath the Antarctic Ice Sheet reveal the geomorphological history of Jutulstraumen Basin

Preserved landscapes underneath the Antarctic Ice Sheet reveal the geomorphological history of Jutulstraumen Basin

Deep ice as a geochemical reactor: insights from iron speciation and mineralogy of dust in the Talos Dome ice core (East Antarctica)

Investigating the internal structure of the Antarctic ice sheet: the utility of isochrones for spatiotemporal ice-sheet model calibration

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