Abstract
The stability of the West Antarctic Ice Sheet is threatened by the incursion of warm Circumpolar Deepwater which flows southwards via cross-shelf troughs towards the coast there melting ice shelves. However, the onset of this oceanic forcing on the development and evolution of the West Antarctic Ice Sheet remains poorly understood. Here, we use single- and multichannel seismic reflection profiles to investigate the architecture of a sediment body on the shelf of the Amundsen Sea Embayment. We estimate the formation age of this sediment body to be around the Eocene-Oligocene Transition and find that it possesses the geometry and depositional pattern of a plastered sediment drift. We suggest this indicates a southward inflow of deep water which probably supplied heat and, thus, prevented West Antarctic Ice Sheet advance beyond the coast at this time. We conclude that the West Antarctic Ice Sheet has likely experienced a strong oceanic influence on its dynamics since its initial formation.
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Introduction
Today, 25–35% of the West Antarctic Ice Sheet (WAIS) drain into the Amundsen Sea Embayment (ASE)1,2. Warm Circumpolar Deepwater (CDW) is currently upwelling on the ASE slope and then flows along the eastern and central parts of deep bathymetric troughs at 118° W (Dotson-Getz Trough DGT), 113°W (Pine Island Trough West PITW), and 108–102°W (Pine Island Trough East PITE and Abbot Trough AT) across the up to 400 km wide continental shelf to the coast3,4 (Fig. 1). CDW then impinges into sub-ice shelf cavities and reaches the WAIS grounding zones, thereby causing sub-ice shelf melting and threatening the stability of the WAIS (e.g., refs. 5,6,7,8). Study of proxies in shelf sediment cores indicates similar sensitivity extends over millennia9. Although modelling studies simulate past WAIS collapses driven primarily by warm water incursion, e.g., during the Pliocene and some Quaternary interglacial periods10,11, there is little observational evidence recording the effects of oceanographic circulation on the longer term history of the ice sheet. This applies also to its initial advance onto the continental shelf.
Continental-scale Antarctic ice sheets are reported to have reached sea level during the EOT following a drop in temperature and atmospheric CO2, which is documented in the Earliest Oligocene Oxygen Isotope Step (EOIS)12,13,14,15,16. The influence of the ocean on the formation and advance/retreat of the Antarctic ice sheets at this time is unconstrained, since the ocean circulation and location of the Southern Ocean frontal system during the Oligocene are still debated17,18. Various scenarios have been suggested based on regional studies. An East Antarctic Ice Sheet (EAIS) with a size fluctuating between larger and smaller than today was reconstructed for the time interval from 34.1 to 32.7 Ma based on clast abundance variability in shelf sediments from Cape Roberts in the southwestern Ross Sea16, whereas a much reduced EAIS during the Early Oligocene, except for the time period from 33.6–32.1 Ma, was inferred from microfossils in sediments recovered offshore from the Wilkes Land region, East Antarctica19. Olivetti, et al.20 concluded from the provenance of some of the clasts in the Cape Roberts sediments their origins from sources in the Transantarctic Mountains south of Byrd Glacier, implying that the WAIS may have advanced onto the Ross Sea shelf already during cold periods of the Early Oligocene from about 32 Ma onwards. Furthermore, both bathymetry and width of the Antarctic continental shelves and therefore the potential pathways of deep water flow towards the grounding zone of the ice sheet changed significantly since the onset of glaciation but the exact timing and rates of these changes remain uncertain21,22. Knowledge of the palaeobathymetry is essential to identify possible water mass pathways such as troughs and channels, allowing the protrusion of warm deep water from the shelf break across the shelf and to the ice-sheet margins. Areas currently most vulnerable to deep water intrusions, such as the entire East Pacific margin of Antarctica, are severely underrepresented in numerical simulations of palaeoenvironmental changes in Antarctica and the Southern Ocean across the EOT (including data-model comparisons). Reconstructions currently are only available for the East Tasman Plateau, New Zealand, and the Ross Sea23.
Here, we present seismic reflection data combined with age information from shallow seabed drill cores from the ASE shelf to investigate potential palaeo-intrusions of deep water at the EOT by analysing the architecture of a sediment body identified in seismic profiles.
Results
Seismic reflection data collected in Pine Island Trough (PIT) reveal an asymmetric sediment body at the eastern flank of the trough. The sediment body shows a well-stratified convex-up mounded morphology with its thicker part plastered against reflection ASS-u2, and it progressively thins towards the west (Fig. 2, blue horizon- top, cyan horizon- base of the sediment body). Reflection ASS-u2 generally slopes north-westward but shows a local high below the eastern part of today’s PIT (Fig. 2). The sediment body is characterised by internal reflections (thin blue lines in Fig. 2) of good lateral continuity, which terminate (red arrows in Fig. 2) against the body’s base reflection ASS-u2 (downlap, onlap) and top (truncation). The internal reflections mark subunits of the sediment body, which mimic its general shape and in their extent document the growth of the sediment body from the east towards the west (Fig. 2). The sediment body shows a maximum thickness of around 250 ms two-way travel time (∼310 m using a mean conversion velocity of 2500 m/s as derived during processing) and covers an area of ∼310 km2. Its shallowest point lies in the southeast (Fig. 3), where the maximum in thickness is observed. The sediment body is well stratified, which is inconsistent with a glacial origin, e.g., formation as a grounding zone wedge or moraine, since those features typically possess a semi-transparent to chaotic seismic character24,25. Based on its geometry and depositional pattern (convex-up morphology, mounded, well-stratified, good lateral continuity, progressive thinning), the sediment body is interpreted as a plastered sediment drift (see, e.g., Fig. 14.9 of Faugères and Stow26). Sediment drifts are shaped by bottom currents interacting with bathymetry and available detritus27,28. Plastered drifts are mounded sediment bodies located along gentle slopes swept by low-velocity bottom currents29. The sediment body identified in PIT is not associated with a moat but plastered drifts do not necessarily have a moat30,31,32.
The Coriolis effect strongly influences the internal flow structure of an oceanic current, deflecting the downstream velocity core towards the left on the southern hemisphere33,34. Therefore, detritus supplied in meltwater plumes originating from the ice sheet margin in the south and flowing northwards would result in deposition on the western flank of a trough or channel, there shaping sediment drifts. The same would apply to northward transport of fluvial sediment input. However, reflection ASS-u2, which forms the sediment drift’s base, does not show a trough. A sediment drift below the western flank of present-day PIT can neither be identified (Fig. 2c). A sediment body plastered to the eastward rising reflection ASS-u2 thus can only have been shaped by a southward flowing water mass (Fig. 4).
The plastered drift is identified in the lower part of seismic unit ASS-3 (Fig. 2, refs. 35,36). Seismic unit ASS-3 forms one of six seismic units identified on the Amundsen Sea shelf (ASS)35,37. The seismic units are separated by seismic unconformities ASS-u1 to ASS-u5. Seismic units ASS-1 and ASS-2 were sampled at seabed drill Site PS104_20-2 and found to be of Late Cretaceous age and Late Eocene (40 Ma or younger) age, respectively36 (Figs. 5 and 6). Seismic horizon ASS-u1 thus forms an unconformity separating the Cretaceous (seismic unit ASS-1) from the Late Eocene strata (seismic unit ASS-2), which has a thickness of ∼550 ms (∼640 m using conversion velocities as derived from processing) at the location of Site PS104_21-3. The drift body down- and onlaps onto seismic horizon ASS-u2 (Fig. 2), which forms the top of seismic unit ASS-2. In this part of the ASE shelf, this reflection is observed as a conformable seismic horizon indicating non-deposition or a change in deposition. The lower part of seismic unit ASS-3 itself was sampled during RV Polarstern Expedition PS104 in 2017 (Site PS104_21-3 located ∼12 km west of the drift, see Figs. 1, 2c and 5, cf. Klages, et al.38). The dinoflagellate cysts Lejeunecysta katatonos and L. acuminata, which have been used as regional biostratigraphic markers of the Rupelian stage in marine sediments offshore Wilkes Land and at Cape Roberts, East Antarctica39,40, regularly occur at Site PS104_21-3. Lejeunecysta specimen are well preserved and their dominance throughout the entire record provides no evidence of any reworking. Seismic horizon ASS-u2 can be found about 200 m below the base of Site PS104_21-3. A rough age estimate for seismic horizon ASS-u2 can be derived assuming a constant sedimentation rate for seismic units ASS-2 (∼640 m thickness, max 40 Ma36) and the ∼200 m of sediment observed between seismic horizon ASS-u2 and the base of Site PS104_21-3 (33.8 ± 0.6 Ma38). The resulting sedimentation rate of 14 cm/ky is not unrealistic36. This then places seismic horizon ASS-u2 at ∼35 Ma, i.e., the latest Eocene or around the Eocene/Oligocene boundary and, in combination with the biostratigraphic age, the formation of the plastered drift into the latest Eocene or earliest Oligocene.
The first advances of grounded ice to the middle shelf have been inferred for seismic units younger than ASS-335 (Fig. 6). Truncational erosion of older strata, aggradational deposition on the outer shelf and increasing formation of prograding sequences commenced in seismic unit ASS-4.
Seismic horizon ASS-u2 (Eocene/Oligocene boundary?) underlying the sediment drift (Fig. 3a) gently dips northwestward. The palaeotopographic/palaeobathymetric reconstructions of Paxman, et al.22 and Hochmuth, et al.41 for 34 Ma similarly show a seafloor rising towards the east in this area, which would have facilitated the formation of plastered drifts by low velocity bottom currents (Fig. 3b). Biostratigraphic and palaeoenvironmental evidence from sediment cores collected in the area of the West Antarctic Rift System (WARS), Marie Byrd Land42, provide additional constraints for the palaeo-depth of this region of West Antarctica. This is only consistent with the minimum palaeotopography/palaeobathymetry of Paxman, et al.22 and Hochmuth, et al.41, which we therefore use for our interpretation. The minimum palaeotopography/palaeobathymetry has been adjusted for flexural isostasy (rebound for ice sheet loading) and sea level variations22,41. Furthermore, the absence of an ice sheet or even the far distance to an ice sheet or high-elevation ice-cap will not have had a significant isostatic effect on the shelf. Geometry and internal reflection configuration of a plastered drift result from the flow direction of the shaping water mass. A drift crest and the thickest accumulation document deposition to one side of the path of strongest flow, whereas erosion/non-deposition occurs below the flow path34. The observed drift is plastered to the eastward rising flank of seismic horizon ASS-u2 with the shallowest and thickest part in the southeast (the drift crest) (Fig. 2). The drift shows thinning towards the north and west. This drift geometry points towards a southward water mass transport (Fig. 2, open circles with dots indicate a flow path out of the figure plane, and 3, red arrow) with the Coriolis effect enhancing deposition on the left-hand side33,43, i.e., the same flow direction as today’s CDW. The overall form of the sediment drift influences the present-day seabed morphology, as documented in the mounded structure observed at the seafloor on seismic profiles AWI-20170012 (CDPs 1550 to 2100) and AWI-20100137 (CDPs 600 to 1500) (Fig. 2).
Since we can rule out the formation by subglacial processes, meltwater pulmes, or sediment supplied by rivers, we hypothize that a southward flowing deep water mass, which has upwelled onto the continental shelf, shaped the observed drift between the Late Eocene and Early Oligocene. A deep water mass impinging on the shelf would have been capable of shaping a sediment drift, as can be seen by comparison to today’s CDW44,45. Deep water masses can intrude onto continental shelves due to Ekman driven pull46 particularly where the shelf break is interrupted by troughs or canyons3,4 (see paleo-trough mouth/canyon in the shelf break in Figs. 3 and 7). There, they can then form shallow water sediment drifts47,48. Sediments retrieved at Site PS104_20-2 about 30 km south of the observed sediment drift (Fig. 5) and at Site PS104_21-3 north of the drift northwest of the drift indicate a temperate and cool-temperate Late Eocene (Extended Data Fig. 4 of Klages, et al.)36 and Early Oligocene38, respectively. Material input via a coastal/estuarine system and/or resulting from biogenic productivity would have been entrained by the southward flowing deep water thus shaping the observed sediment drift (Figs. 3 and 7).
Mertz Drift on the George V Land shelf, East Antarctica, is an example for a sediment drift formed by upwelling of deep water onto the shelf and shows similarities to the drift observed on the ASE shelf. The drift is located in an ∼850 m deep trough on the shelf and covers an area of ∼400 km2,44,49. The drift is max 20 m thick and shows a well-stratified mounded structure with a steeper flank in the southwest. It appears plastered to the eastern flank of the trough. Mertz Drift is interpreted to have been formed by modified CDW upwelling onto the shelf44,45,49. Both the inflow and outflow of modified CDW entrain and transport fine-grained detritus shaping Mertz Drift. Sediment cores have shown that Mertz Drift is covered by a layer of glacimarine sediments deposited at or after the Last Glacial Maximum LGM, which, together with seismic data, indicate that Mertz Drift was formed in pre and/or at the LGM times and provides evidence for deep water upwelling onto the shelf during these times45. The sediment drift observed on the ASE shelf has a similar spatial extent as Mertz Drift and has also been formed against a south- and westward sloping seafloor (see Fig. 3).
So far, no such sediment drifts associated with CDW have been observed in the outer parts of the western and eastern Pine Island Troughs and Abbot Trough. However, seismic coverage of the outer ASE shelf is sparse, and often a dense sea ice cover limits both the acquisition and quality of the seismic data.
Discussion
Observations constraining the palaeoceanography and palaeoenvironment of the Amundsen Sea during the EOT are very limited. This knowledge is essential to understand the regional and chronological development and stability of glaciation within the different sectors of Antarctica, especially in areas where today marine based ice sheets are observed17. While local ice caps at low altitudes are assumed to have existed in Marie Byrd Land as early as 29–27 Ma50,51, and the WAIS may episodically have advanced onto the Ross Sea shelf during cold periods around 32 Ma already20, biostratigraphic and palaeoenvironmental evidence in sediments recovered from beneath the WAIS indicate marine incursions into the WARS between the Marie Byrd Land coast and the Transantarctic Mountains for the Late Paleogene Marine Event (∼34.5–31.5 Ma)42.
According to Paxman, et al.22, the hinterland of the ASE was mostly above sea-level at the EOT, unlike today. This suggests that any early kind of a WAIS was still far away from the shelf. Therefore, any end moraines or other glacio-morphological features documenting former ice-sheet extent would have been restricted to areas on land but not on the shelf.
Deep ocean temperatures were cooler in the Early Oligocene and the seasonality was more pronounced than during the Eocene52. Warmer deep water has been reported for the Wilkes Land margin and the Ross Sea19,53,54,55. The opening of the Tasmanian Gateway has had a strong effect on the circulation and ocean temperatures near Wilkes Land56,57 while east of the Tasman Rise a proto-Ross gyre already existed before the opening56,58. The proto-Ross gyre would have deflected oceanographic frontal systems southwards towards the continental slope at its eastern flank, where the Amundsen Sea is located, potentially driving upwelling onto the ASE shelf as observed today (Fig. 3) (e.g., refs. 59,60,61). Therefore, the effect of the opening of the Tasmanian Gateway may not have fundamentally changed the circulation in the ASE.
Several studies suggest that conditions for a proto-Antarctic Circumpolar Current (ACC) were met already during the Late Eocene62,63,64. This resulted in upwelling in the high-latitude South Pacific63, which was further increased after opening of the Drake Passage in the Early Oligocene62. During warm phases in the Oligocene the westerly wind system is thought to have migrated further south, which in combination with weak easterlies and a moderate ACC flow would have favoured upwelling of deep water onto the Antarctic shelf19,55, especially where troughs/canyons interrupted the shelf break3,4, and therefore possibly facilitated drift formation on the ASE shelf. A westerly wind system located further north, moderate easterlies and a weak ACC during cold phases in the Oligocene would have resulted in weak upwelling onto the shelf55.
Our new seismic data have revealed a mounded structure interpreted as a sediment drift resulting from deep water upwelling onto the ASE shelf in the latest Eocene or earliest Oligocene. This upwelling was probably related to a southerly location of the ACC fronts during a warm phase. Upwelling of deep waters far onto the shelf was most likely further enhanced by the presence of a trough/channel in the ASE shelf break (Figs. 3 and 7). The deep water was then steered by the south-eastward rising seafloor and shaped the sediment drift picking up material provided by a coastal/estuarine system or biogenic production36. We propose that the intrusions of potentially warm deep water prevented a cooling of shelf waters and thus an advance of an ice sheet onto the ASE shelf during the globally observed cooling in conjunction with the EOT by buffering heat on the shelf. Later in the Oligocene, increasing global cooling will have relocated the westerly wind system northwards and influenced the intensity of upwelling. This may have ended the formation of the observed sediment drift plastered against seismic horizon ASS-u2 below the eastern flank of the present-day PIT.
The bathymetric/topographic setting in the ASE is different from the other sectors of Antarctica. Paxman, et al.22’s minimum reconstruction for 34 Ma shows much higher elevations for East Antarctica while the Ross Sea area and the ASE are largely located below sea level. A cooling in East Antarctica thus will have had a stronger effect enabling the growth of larger ice sheets as has been suggested for the Ross Sea sector of Antarctica16,55. Olivetti, et al.20 also suggested Early Oligocene marine terminating ice in the Ross Sea sector but an extensive advance into the marine realm was only inferred for close to the Oligocene-Miocene boundary. The ASE shelf thus may have been the last Antarctic sector that experienced full glaciation since here oceanic circulation influenced by bathymetry appears to have delayed advance of the WAIS during the EOT. Therefore, our results highlight the importance of oceanic forcing for the evolution of the WAIS since the onset of Antarctic glaciation.
Methods
The study is based on the analysis of single- (SCS) and multichannel (MCS) seismic reflection profiles gathered in the Amundsen Sea Embayment65,66,67. SCS line NBP9902-11 was collected using a 3.36 l GI-gun™ and a single channel streamer. The MSC data were collected with up to three GI-guns™ (1.68 l volume each GI-gun used to generate the signal) and different streamer systems (240 channel, 3000 m long in 2010, 96 channel, 600 m long streamer in 2017) (Table 1). The MCS data were recorded with a sample rate of 1 ms while line NP9902-11 was recorded with a sample rate of 0.25 ms. Standard data processing was applied to all MCS lines comprising CDP sorting, velocity analysis, stacking and migration. To suppress seafloor multiples as much as possible we applied various processing strategies including filtering in the frequency–wave number (f–k) domain prior to stacking and migration (Table 1). A ghost reflection (e.g., Fig. 2b) results from the energy traveling upward from the seismic pulse to the sea surface and there is reflected downward. This reflected ghost pulse follows the primary down going pulse by a time interval determined by the depth of the emitted seismic pulse68. Unfortunately, processing has not always successfully suppressed the ghost reflection (see Fig. 2b). The ASE shelf is characterized by glacial overcompaction and erosion limiting the penetration of the seismic signal.
The seismic data (Supplementary Fig. 1) were analysed to identify sediment drifts, which are shaped by bottom currents. Those bottom currents comprise deep or bottom water and are driven by thermohaline circulation. They persist for long periods of time (>104 y) and can develop equilibrium conditions69. Sediment drifts usually form asymmetric, mounded, elongated sediment bodies with a steep and a less inclined flank70. The mounds show discontinuities at their bases and often internal discontinuities. The internal reflections show onlap and downlap onto the discontinuities as well as truncation at the top. In general, the different seismic units forming these mounds are lenticular and upward convex. The vertical stacking of the seismic units may show a lateral migration resulting from the relocation of the shaping current. Variations in climate, sea-level, and bottom circulation lead to an alternation in the dominating sediment transport process70,71.
The interpretation of seismostratigraphic units and unconformities is based on Gohl, et al.35 aided by age information from two shallow seabed drill cores, PS104_20-2 (for more details see Klages, et al.36) and PS104_21-3 (see below, cf. Klages, et al.38). The seismostratigraphic analysis of a set of seismic reflection data from the ASE shelf and slope revealed six major sedimentary units (ASS-1 to ASS-6, ASS = Amundsen Sea Shelf) separated by five major erosional unconformities (ASS-u1 to ASS-u5) from bottom to top. Via a comparison of the observed seismic characteristics with those of other Antarctic shelf sequences ages were assigned to the different sedimentary units. With the aid of the two shallow seabed drill cores taken in 201772, seismic horizon ASS-u1 was dated to represent a hiatus from the Late Cretaceous to at least the Late Eocene36, unit ASS-2 was interpreted as Late Eocene-Oligocene (?)36 and unit ASS-3 was assigned to the Oligocene to Miocene.
Core PS104_21-3 was collected during RV Polarstern expedition PS104 in 2017 using a remotely operated seafloor drill rig. For technical and operational details see Gohl, et al.72. We reconstructed the position of the drill sites in Fig. 3 in accordance with the palaeotopographic/palaeobathymetric reconstruction by Paxman, et al.22 and Hochmuth, et al.41.
A total of seven samples from core PS104_21-3 have been processed for biostratigraphic (palynological) analyses following standard palynological techniques, including sieving (10 μm) and acid treatment with 10% HCl (Hydrochloric acid) and cold 38% HF (Hydrofluoric acid). The samples showed a general low diversity of dinoflagellate cysts with a dominance of taxa of the genus Lejeunecysta, including the age indicative L. katatonos and L. acuminata.
Data availability
All data needed to evaluate the conclusions in the paper are present in the main text or the Supplementary materials. All data are publicly available at the following repositories: AWI seismic data, Pangaea (https://doi.org/10.1594/PANGAEA.933264, https://doi.org/10.1594/PANGAEA.933266, https://doi.org/10.1594/PANGAEA.933265, https://doi.org/10.1594/PANGAEA.933269)73,74,75,76, NBP9902 seismic data, IEDA (https://doi.org/10.1594/IEDA/307363)77.
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Acknowledgements
We thank the captains and crews of RV Polarstern Expeditions ANT-XXVI/3 and PS104, as well as the MARUM-MeBo70 and the seismic teams for their support. We further thank Brian Romans and two anonymous reviewers for their very helpful comments and suggestions, which improved the manuscript. The authors would like to thank Emerson E&P Software, Emerson Automation Solutions, for providing licenses for their seismic processing and mapping software Paradigm in the scope of the Emerson Academic Program. The operation of the MARUM-MeBo70 Sea Floor Drill Rig was funded by the Alfred Wegener Institute (AWI) through its Research Program PACES II Topic 3 and grant no. AWI_PS104_001, the MARUM Center for Marine Environmental Sciences, the British Antarctic Survey through its Polar Science for Planet Earth programme, and the Natural Environmental Research Council funded UK IODP programme. G.U.-N., K.G. and J.P.K. were funded by the AWI PACES II programme. J.P.K. was further funded by the Helmholtz Association (PD-201). BAS and NERC UK IODP funded UK participation in expedition PS104.
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G.U.-N. conceived the idea and led the study, and together with K.G., K.H., U.S. and R.D.L. wrote the manuscript with contributions from all co-authors. J.P.K. and C.-D.H. led the analytical program of the MeBo drill cores, and U.S. provided the biostratigraphic age. G.U.-N., K.G., K.H. and R.D.L. undertook the seismic surveys, and G.U.-N. and K.G. processed the seismic data. All members of the Expedition PS104 Science Team helped in pre-site survey investigations, core recovery, on-board analyses and/or shore based measurements. K.G., G.U.-N., R.D.L. and C.-D.H. acquired funding, and amongst others, proposed, and planned RV Polarstern expeditions ANT-XXVI/3 and PS104. All co-authors commented on the manuscript and provided input to its final version.
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Communications Earth & Environment thanks Brian Romans, Tanghua Li and the other, anonymous, reviewer(s) for their contribution to the peer review of this work. Primary Handling Editors: Adam Switzer, Joe Aslin.
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Uenzelmann-Neben, G., Gohl, K., Hochmuth, K. et al. Deep water inflow slowed offshore expansion of the West Antarctic Ice Sheet at the Eocene-Oligocene transition. Commun Earth Environ 3, 36 (2022). https://doi.org/10.1038/s43247-022-00369-x
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DOI: https://doi.org/10.1038/s43247-022-00369-x
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