Pathways of ocean heat towards Pine Island and Thwaites grounding lines

Nakayama, Yoshihiro; Manucharyan, Georgy E.; Zhang, Hong; Dutrieux, Pierre; Torres, Héctor; Klein, Patrice; Seroussi, Hélène; Schodlok, Michael; Rignot, Eric; Menemenlis, Dimitris

doi:10.1038/s41598-019-53190-6

Cited by 62 publications

(96 citation statements)

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“…It is clear from our results that the increased spatial resolution of the MBES data is critical for capturing the high-frequency bathymetric variability on the inner continental shelf seaward of TG, which is necessary to understand warm water incursions into sub-ice shelf cavities (Figs. 8, S5;Nakayama et al, 2019). The strong correlation of our observations with interpretations of the present bed conditions of TG and, therefore, the robustness of this deglaciated terrain as an analogue for the modern bed, further demonstrates that more information can be gleaned from this type of marine dataset (i.e.…”

Section: Implications From the New Bed Roughness Datasupporting

confidence: 65%

“…3a); oceanographic measurements and models confirm that this deep acts as a pathway for CDW towards grounding lines in western Pine Island Bay ( Fig. 2a) (Dutrieux et al, 2014;Nakayama et al, 2019).…”

Section: New Bathymetric Compilation For the Inner Amundsen Sea Embaymentioning

confidence: 79%

“…The need for high-resolution bathymetry was underscored by recent predictive modelling studies of Antarctic outlet glaciers, which conclude that the shape of the ice-shelf cavity and knowledge of small, kilometre-scale pinning points are both key to improving predictions of ice-sheet retreat and sea-level change (Berger et al, 2016;Favier et al, 2016). Similarly, the latest high-resolution ocean models demonstrate that warm deep water reaches the grounding zone of TG through topographically-constrained pathways, again highlighting the critical need for high-resolution bathymetry in making accurate predictions (Nakayama et al, 2019).…”

Section: Implications From the New Bathymetric And Geomorphological Datamentioning

confidence: 98%

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Revealing the former bed of Thwaites Glacier using sea-floor bathymetry

Hogan

Larter

Graham

et al. 2020

Preprint

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Abstract. The geometry of the sea floor beyond Thwaites Glacier (TG) is a major control on the routing of warm ocean waters towards the ice stream’s grounding zone, which has led to increased mass loss through sub-ice-shelf melting and resulting accelerated ice flow. Nearshore topographic highs act as pinning points for the Thwaites Ice Shelf and potentially provide barriers to warm water incursions. To date, few vessels have been able to access this area due to persistent sea-ice and iceberg cover. This critical data gap was addressed in 2019 during the first cruise of the International Thwaites Glacier Collaboration (ITGC) project, with more than 2000 km2 of new multibeam echo-sounder data (MBES) were acquired offshore TG. Here, these data along with legacy MBES datasets are compiled to produce a set of standalone bathymetric grids for the inner Amundsen Sea shelf beyond both Pine Island and Thwaites glaciers. At TG, the bathymetry is dominated by a > 1200 m deep, structurally-controlled trough and discontinuous ridge, on which the Eastern Ice Shelf is pinned. The geometry and composition of the ridge varies spatially with some parts having distinctive flat-topped morphologies produced as their tops were planed-off by erosion at the base of the seaward-moving Thwaites Ice Shelf, suggesting a positive feedback mechanism for ice-shelf ungrounding. Knowing that this offshore area is a former bed for TG, we applied a novel spectral approach to investigate bed roughness and find that derived power spectra can be approximated using an inverse-square law, a result that is consistent with spectra for bed profiles from the modern TG. Using existing ice-flow theory, we also make a first assessment of the form drag (basal drag contribution) for ice flow over this topography. Ice flowing over the sea-floor troughs and ridges would have been affected by similarly high basal drag to that acting in the grounding zone today. We show that the sea-floor bathymetry is an analogue for extant bed areas of TG and that more can be gleaned from these 3D bathymetric datasets regarding the likely spatial variability of bed roughness and bed composition types underneath TG. Comparisons with existing regional bathymetric compilations for the area show that high-frequency (finer than 5 km) bathymetric variability beyond Antarctic ice shelves can only be resolved by observations such as MBES and that without these data calculations of the capacity of bathymetric troughs, and thus oceanic heat flux, may be significantly underestimated. This work meets the requirements of recent numerical ice-sheet and ocean modelling studies that have recognised the need for accurate and high-resolution bathymetry to determine warm water routing to the grounding zone and, ultimately, for predicting glacier retreat behaviour.

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Section: Implications From the New Bed Roughness Datasupporting

confidence: 65%

Section: New Bathymetric Compilation For the Inner Amundsen Sea Embaymentioning

confidence: 79%

Section: Implications From the New Bathymetric And Geomorphological Datamentioning

confidence: 98%

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Revealing the former bed of Thwaites Glacier using sea-floor bathymetry

Hogan

Larter

Graham

et al. 2020

Preprint

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“…1) (e.g. Nitsche et al, 2007;Walker et al, 2007;Jacobs et al, 2012;Nakayama et al, 2013). Landward of the MBES data coverage that existed prior to this study, gravity inversions had indicated the presence of a NE-SWtrending ridge on which the EIS is pinned (Rignot, 2001;Tinto and Bell, 2011;Millan et al, 2017).…”

Section: Introductionmentioning

confidence: 83%

“…Regional bathymetry for the Amundsen Sea Embayment and location of Thwaites Glacier (TG), West Antarctica. Bathymetry is from IBCSO (Arndt et al, 2013); arrows show observed (solid) and inferred (dashed) pathways for CDW across the continental shelf towards the grounding zones of Pine Island, Thwaites and Smith glaciers (following Nakayama et al, 2013;Dutrieux et al, 2014) and along the Dotson-Getz trough (Ha et al, 2014). PIT is Pine Island Trough; PITE is Pine Island Trough East; PITW is Pine Island Trough West; TGT is Thwaites Glacier Tongue; EIS is Eastern Ice Shelf; other ice shelves (I.S.)…”

Section: Introductionmentioning

confidence: 99%

Revealing the former bed of Thwaites Glacier using sea-floor bathymetry: implications for warm-water routing and bed controls on ice flow and buttressing

et al. 2020

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Abstract. The geometry of the sea floor immediately beyond Antarctica's marine-terminating glaciers is a fundamental control on warm-water routing, but it also describes former topographic pinning points that have been important for ice-shelf buttressing. Unfortunately, this information is often lacking due to the inaccessibility of these areas for survey, leading to modelled or interpolated bathymetries being used as boundary conditions in numerical modelling simulations. At Thwaites Glacier (TG) this critical data gap was addressed in 2019 during the first cruise of the International Thwaites Glacier Collaboration (ITGC) project. We present more than 2000 km2 of new multibeam echo-sounder (MBES) data acquired in exceptional sea-ice conditions immediately offshore TG, and we update existing bathymetric compilations. The cross-sectional areas of sea-floor troughs are under-predicted by up to 40 % or are not resolved at all where MBES data are missing, suggesting that calculations of trough capacity, and thus oceanic heat flux, may be significantly underestimated. Spatial variations in the morphology of topographic highs, known to be former pinning points for the floating ice shelf of TG, indicate differences in bed composition that are supported by landform evidence. We discuss links to ice dynamics for an overriding ice mass including a potential positive feedback mechanism where erosion of soft erodible highs may lead to ice-shelf ungrounding even with little or no ice thinning. Analyses of bed roughnesses and basal drag contributions show that the sea-floor bathymetry in front of TG is an analogue for extant bed areas. Ice flow over the sea-floor troughs and ridges would have been affected by similarly high basal drag to that acting at the grounding zone today. We conclude that more can certainly be gleaned from these 3D bathymetric datasets regarding the likely spatial variability of bed roughness and bed composition types underneath TG. This work also addresses the requirements of recent numerical ice-sheet and ocean modelling studies that have recognised the need for accurate and high-resolution bathymetry to determine warm-water routing to the grounding zone and, ultimately, for predicting glacier retreat behaviour.

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