17 results on '"Rydningen, Tom Arne"'
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2. Contrasting Neogene–Quaternary continental margin evolution offshore mid-north Norway: Implications for source-to-sink systems
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Bjordal-Olsen, Stine, Rydningen, Tom Arne, Laberg, Jan Sverre, Lasabuda, Amando P.E., and Knutsen, Stig-Morten
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- 2023
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3. Late Weichselian and Holocene behavior of the Greenland Ice Sheet in the Kejser Franz Josef Fjord system, NE Greenland
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Olsen, Ingrid Leirvik, Laberg, Jan Sverre, Forwick, Matthias, Rydningen, Tom Arne, and Husum, Katrine
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- 2022
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4. Cenozoic uplift and erosion of the Norwegian Barents Shelf – A review
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Lasabuda, Amando P.E., Johansen, Nora S., Laberg, Jan Sverre, Faleide, Jan Inge, Senger, Kim, Rydningen, Tom Arne, Patton, Henry, Knutsen, Stig-Morten, and Hanssen, Alfred
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- 2021
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5. Glacial history of the Åsgardfonna Ice Cap, NE Spitsbergen, since the last glaciation
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Allaart, Lis, Schomacker, Anders, Larsen, Nicolaj K., Nørmark, Egon, Rydningen, Tom Arne, Farnsworth, Wesley R., Retelle, Michael, Brynjólfsson, Skafti, Forwick, Matthias, and Kjellman, Sofia E.
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- 2021
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6. Depositional processes on the distal Scoresby Trough Mouth Fan (ODP Site 987): Implications for the Pleistocene evolution of the Scoresby Sund Sector of the Greenland Ice Sheet
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Laberg, Jan Sverre, Rydningen, Tom Arne, Forwick, Matthias, and Husum, Katrine
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- 2018
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7. Seabed morphology and sedimentary processes on high-gradient trough mouth fans offshore Troms, northern Norway
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Rydningen, Tom Arne, Laberg, Jan Sverre, and Kolstad, Vidar
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- 2015
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8. A High Arctic inner shelf–fjord system from the Last Glacial Maximum to the present: Bessel Fjord and southwest Dove Bugt, northeastern Greenland.
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Zoller, Kevin, Laberg, Jan Sverre, Rydningen, Tom Arne, Husum, Katrine, and Forwick, Matthias
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LAST Glacial Maximum ,FJORDS ,GREENLAND ice ,WATERSHEDS ,ICE caps - Abstract
The Greenland Ice Sheet (GrIS) responds rapidly to the present climate; therefore, its response to the predicted future warming is of concern. To learn more about the impact of future climatic warming on the ice sheet, decoding its behavior during past periods of warmer than present climate is important. However, due to the scarcity of marine studies reconstructing ice sheet conditions on the Northeast Greenland shelf and adjacent fjords, the timing of the deglaciation over marine regions and its connection to forcing factors remain poorly constrained. This includes data collected in fjords that encompass the Holocene thermal maximum (HTM), a period in which the climate was warmer than it is at present. This paper aims to use new bathymetric data and the analysis of sediment gravity cores to enhance our understanding of ice dynamics of the GrIS in a fjord and inner shelf environment as well as give insight into the timing of deglaciation and provide a palaeoenvironmental reconstruction of southwestern Dove Bugt and Bessel Fjord since the Last Glacial Maximum (LGM). North–south-oriented glacial lineations and the absence of pronounced moraines in southwest Dove Bugt, an inner continental shelf embayment (trough), suggest the southwards and offshore flow of Storstrømmen, the southern branch of the Northeast Greenland Ice Stream (NEGIS). Sedimentological data suggest that an ice body, theorized to be the NEGIS, may have retreated from the region slightly before ∼ 11.4 cal ka BP. The seabed morphology of Bessel Fjord, a fjord terminating in southern Dove Bugt, includes numerous basins separated by thresholds. The position of basin thresholds, which include some recessional moraines, suggest that the GrIS had undergone multiple halts or readvances during deglaciation, likely during one of the cold events identified in the Greenland Summit temperature records. A minimum age of 7.1 cal ka BP is proposed for the retreat of ice through the fjord to or west of its present-day position in the Bessel Fjord catchment area. This suggests that the GrIS retreated from the marine realm in Early Holocene, around the onset of the HTM in this region, a period when the mean July temperature was at least 2–3 ∘ C higher than at present and remained at or west of this onshore position for the remainder of the Holocene. The transition from predominantly mud to muddy sand layers in a mid-fjord core at ∼ 4 cal ka BP may be the result of increased sediment input from nearby and growing ice caps. This shift may suggest that in the Late Holocene (Meghalayan), a period characterized by a temperature drop to modern values, ice caps in Bessel Fjord probably fluctuated with greater sensitivity to climatic conditions than the northeastern sector of the GrIS. [ABSTRACT FROM AUTHOR]
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- 2023
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9. The marine-based NW Fennoscandian ice sheet: glacial and deglacial dynamics as reconstructed from submarine landforms
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Rydningen, Tom Arne, Vorren, Tore O., Laberg, Jan Sverre, and Kolstad, Vidar
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- 2013
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10. Southern outlet of the Northeast Greenland Ice Stream, NE Greenland: post-Last Glacial Maximum response to climate warming.
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Zoller, Kevin, Laberg, Jan Sverre, Rydningen, Tom Arne, Husum, Katrine, and Forwick, Matthias
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ICE streams ,LAST Glacial Maximum ,CLIMATE change ,GLOBAL warming ,ICE sheets - Abstract
The Greenland Ice Sheet (GrIS) responds rapidly to the present climate, therefore, its response to the predicted future warming is of concern. To learn more about this, decoding its behavior during past periods of warmer than present climate is important. However, due to the scarcity of marine studies reconstructing ice sheet conditions on the Northeast Greenland shelf and adjacent fjords including the position of the ice sheet over marine regions, the timing of the deglaciation, and its connection to forcing factors including the Holocene Thermal Maximum (HTM) on NE Greenland remain poorly constrained. This paper aims to use bathymetric data and the analysis of sediment gravity cores to enhance our understanding of ice dynamics of the GrIS near the southern outlet of the Northeast Greenland Ice Stream (NGIS), as well as give insight into the timing of deglaciation and provide a palaeoenvironmental reconstruction of southwestern Dove Bugt and Bessel Fjord since the Last Glacial Maximum (LGM). The swath bathymetry data displayed in this study is the first time the bathymetry for Bessel Fjord has become available. North–south oriented glacial lineations, and the absence of pronounced moraines in southwest Dove Bugt, an inner continental shelf embayment (trough), suggests the southwards and offshore flow of the southern branch of the NGIS, Storstrømmen. Sedimentological data suggests that an ice body, theorized to be the NGIS, may have retreated from the region slightly before ~11.2 ka BP (in the Preboreal period). The seabed morphology of Bessel Fjord, a fjord terminating in southern Dove Bugt, includes numerous basins, separated by thresholds. The position of basin thresholds, which include some recessional moraines, suggest that the GrIS had undergone multiple halts or readvances during deglaciation. A minimum age of 7.2 ka BP is proposed for the retreat of ice to or west of its present-day position in the Bessel Fjord catchment area. This suggests that the GrIS retreated from the marine realm in early Holocene, around the time of the onset of the Holocene Thermal Maximum in this region, a period when the mean July temperature according to Bennike et al., (2008) was at least 2–3 °C higher than at present, and remained at or west of this onshore position for the remainder of the Holocene. The transition from predominantly mud to muddy sand layers in a mid-fjord core at ~4 ka BP may be the result of increased sediment input from nearby and growing ice caps. This shift may suggest that in late Holocene (Meghalayan), a period characterized by a temperature drop to modern values, ice caps in Bessel Fjord fluctuated with greater sensitivity to climatic conditions than the NE sector of the GrIS. [ABSTRACT FROM AUTHOR]
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- 2022
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11. Last glacial ice sheet dynamics offshore NE Greenland – a case study from Store Koldewey Trough.
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Olsen, Ingrid Leirvik, Rydningen, Tom Arne, Forwick, Matthias, Laberg, Jan Sverre, and Husum, Katrine
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ICE sheets , *ICE shelves , *GREENLAND ice , *GLACIAL landforms , *LAST Glacial Maximum , *SUBGLACIAL lakes , *ICE streams , *TOPOGRAPHY - Abstract
The presence of a grounded Greenland Ice Sheet on the northeastern part of the Greenland continental shelf during the Last Glacial Maximum is supported by new swath bathymetry and high-resolution seismic data, supplemented with multi-proxy analyses of sediment gravity cores from Store Koldewey Trough. Subglacial till fills the trough, with an overlying drape of maximum 2.5 m thick glacier-proximal and glacier-distal sediment. The presence of mega-scale glacial lineations and a grounding zone wedge in the outer part of the trough, comprising subglacial till, provides evidence of the expansion of fast-flowing, grounded ice, probably originating from the area presently covered with the Storstrømmen ice stream and thereby previously flowing across Store Koldewey Island and Germania Land. Grounding zone wedges and recessional moraines provide evidence that multiple halts and/or readvances interrupted the deglaciation. The formation of the grounding zone wedges is estimated to be at least 130 years, while distances between the recessional moraines indicate that the grounding line locally retreated between 80 and 400 m yr -1 during the deglaciation, assuming that the moraines formed annually. The complex geomorphology in Store Koldewey Trough is attributed to the trough shallowing and narrowing towards the coast. At a late stage of the deglaciation, the ice stream flowed around the topography on Store Koldewey Island and Germania Land, terminating the sediment input from this sector of the Greenland Ice Sheet to Store Koldewey Trough. [ABSTRACT FROM AUTHOR]
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- 2020
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12. Late Cenozoic Erosion Estimates for the Northern Barents Sea: Quantifying Glacial Sediment Input to the Arctic Ocean.
- Author
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Lasabuda, Amando, Geissler, Wolfram H., Laberg, Jan Sverre, Knutsen, Stig‐Morten, Rydningen, Tom Arne, and Berglar, Kai
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PLIOCENE-Pleistocene boundary ,CONTINENTAL margins ,SEDIMENTATION & deposition ,WATERSHEDS - Abstract
A compilation of seismic data has been used to characterize the Neogene‐Quaternary sedimentary succession of the northwestern Barents Sea continental margin to better understand the paleoenvironmental evolution and the sedimentary processes involved. The Neogene strata are dominated by contourites related to the ocean circulation established from the opening of the Fram Strait connecting the Atlantic and the Arctic Oceans (< ~17.5 Ma). The upper Plio‐Pleistocene strata (< ~2.7 Ma) are dominated by stacked gravity‐driven deposits forming trough‐mouth fans that were sourced from paleo‐ice streams. Within the interfan areas, contouritic sedimentation prevailed. Thus, this margin provides an example of interaction of glacigenic debris flows, contour currents, and hemipelagic/glacimarine sedimentary processes. A total of ~29,000 km3 of sediments with an average sedimentation rate of about 0.24 m/Kyr were estimated. These numbers reflect the sediment input to this part of the Arctic Ocean from the northwestern Barents Sea shelf and adjacent land areas. For the first time, the average erosion and erosion rates for this source area are estimated using a mass balance approach. Approximately 410–650 m of erosion has on average occurred, corresponding to an average erosion rate of ~0.15–0.24 m/Kyr. These rates are comparable to those reported from other glaciated margins, including the western Svalbard and mid‐Norway margin, but up to only half the rates reported from the western Barents Sea margin. This variation is interpreted due to the size and bedrock types of the drainage area, ice dynamics, and the continental slope gradient. Plain Language Summary: This study is about mapping the offshore glacial sediment by using seismic data in the northeastern Svalbard‐northern Barents Sea continental margin. The studied margin provides a unique opportunity to examine an interaction between downslope and along‐slope sediment processes. Development of Kvitøya glacial fan is highlighted and shows a major sediment delivery under ice streams that reached the shelf break. Prior to or at the onset of glaciation, a major slope failure likely occurred generating a large submarine slide, named Body A. For the first time, the average erosion and erosion rates during the last ~2.7 million years are estimated from this margin. We found out that 410–650 m of sediments were removed from the source area. The erosion rates are estimated (0.15–0.24 m/Kyr) and are comparable with other formerly glaciated margins. This study is an important scientific input for a better understanding of uplift and erosion in the Barents Sea shelf. The present contribution is highly relevant for future hydrocarbon exploration in the Barents Sea area and Arctic region. Finally, investigating such subsurface sediments is crucial for paleoenvironmental reconstruction in order to understand the climate dynamics in the past. Key Points: Quantification of the glacial sediment input to the Arctic Ocean from the northwestern Barents Sea is presentedFor the first time, average erosion and erosion rates are estimated from the source area of this margin using a mass balance approachThese rates are comparable to those reported from other glaciated margin, but only about half compared to the western Barents Sea margin [ABSTRACT FROM AUTHOR]
- Published
- 2018
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13. Late Cenozoic evolution of high-gradient trough mouth fans and canyons on the glaciated continental margin offshore Troms, northern Norway--Paleoclimatic implications and sediment yield.
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Rydningen, Tom Arne, Laberg, Jan Sverre, and Kolstad, Vidar
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CENOZOIC Era , *GLACIAL landforms , *CONTINENTAL margins , *PALEOCLIMATOLOGY , *SEDIMENTATION & deposition - Abstract
Trough mouth fans contain information about the evolution of high-latitude continental margins, including rates of glacial sedimentation and hinterland erosion. Here, the late Cenozoic evolution of high-gradient trough mouth fans and canyons on the Troms margin, northern Norway, is reconstructed. Paleocanyons were active prior to the Quaternary glaciations. Glaciomarine and glaciofluvial conditions prevailed between ca. 2.7 Ma and ca. 1.5 Ma, and ice sheets possibly reached the paleo-shelf break at least once. The minimum average sedimentation rate of this period was 0.22 m/k.y. From ca. 1.5 Ma to ca. 0.7 Ma, the glaciations intensified, and fast-flowing ice streams reaching the shelf break were established in the cross-shelf troughs. Subglacial deformation till was deposited at the outer shelf and later reworked by debris flows and turbidity currents. The Fennoscandian Ice Sheet started to route much of its ice mass to the north and south of the study area, and so the Troms margin possibly was a low-ice-flow sector from this time, with a minimum average sedimentation rate of 0.15 m/k.y. During the last ca. 0.7 m.y., ice streams continued to traverse the troughs, while sluggish-flowing ice prevailed on the banks. A minimum average sedimentation rate of 0.14 m/k.y. is estimated for this period. The minimum total erosion and erosion rate for the Quaternary are 50-140 m and 0.02-0.05 m/k.y., respectively. Compared with previous studies from other areas, this implies up to one order of magnitude variation in average glacial erosion rates along the western sector of the Fennoscandian-Barents Sea ice sheets. This is interpreted to be due to the size and bedrock composition of the catchment areas and the timing of ice growth and ice-sheet dynamics. In addition, the steep preglacial continental slope promoted high sediment flow velocity for the glacigenic sediments, causing much of the debris flows to transform into turbidity currents, which efficiently transported sediments across the slope and thereby maintained its steep gradient. [ABSTRACT FROM AUTHOR]
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- 2016
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14. Chronology and extent of the Lofoten-Vesterålen sector of the Scandinavian Ice Sheet from 26 to 16 cal. ka BP.
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Vorren, Tore O., Rydningen, Tom Arne, Baeten, Nicole J., and Laberg, Jan Sverre
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ICE sheets , *GLACIAL melting , *SEA level , *STRATIGRAPHIC geology , *ICE caps - Abstract
The interplay between the onshore and offshore areas during the Last Glacial Maximum and the deglaciation of the Scandinavian Ice Sheet is poorly known. In this paper we present new results on the glacial morphology, stratigraphy and chronology of Andøya, and the glacial morphology of the nearby continental shelf off Lofoten-Vesterålen. The results were used to develop a new model for the timing and extent of the Scandinavian Ice Sheet in the study area during the local last glacial maximum ( LLGM) (26 to 16 cal. ka BP). We subdivided the LLGM in this area into five glacial events: before 24, c. 23 to 22.2, 22.2 to c. 18.6, 18 to 17.5, and 16.9-16.3 cal. ka BP. The extent of the Scandinavian Ice Sheet during these various events was reconstructed for the shelf areas off Lofoten, Vesterålen and Troms. Icecaps survived in coastal areas of Vesterålen-Lofoten after the shelf was deglaciated and off Andøya ice flowed landwards from the shelf. During the LLGM the relative sea level was stable until 18.5 cal. ka BP, and thereafter there was a sea-level drop on Andøya. Thus, relative sea level (i.e. a sea level rise) does not seem to be a driving mechanism for ice-margin retreat in this area but the fall in sea level may have had some importance for the grounding episodes on the banks during deglaciation. The positions of the grounding zone wedges ( GZWs) in the troughs are related to the morphology as they are often located where the troughs narrow. [ABSTRACT FROM AUTHOR]
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- 2015
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15. Inter-trough glacial landforms on the outermost NE Greenland shelf – preliminary results.
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Laberg, Jan Sverre, Rydningen, Tom Arne, Olsen, Ingrid L., Forwick, Matthias, and Husum, Katrine
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GLACIAL landforms , *GREENLAND ice , *LAST Glacial Maximum , *ICE sheets , *SEDIMENT analysis , *GLACIOLOGY - Abstract
Today the Arctic is undergoing far-reaching changes with rising air and sea-water temperatures, and rapidly decreasing glaciers and ice sheets. In order to model future changes of the ice sheet-ocean-atmosphere climate system, it is urgent to obtain more knowledge on the glacier dynamics of the Greenland Ice Sheet. Very little is known about the past evolution of the eastern sector of this ice sheet, e.g. it has not been established where its maximum position was during the Last Glacial Maximum (LGM). Furthermore, neither ice dynamics, sediment production by subglacial erosion or timing and nature of ice recession from the shelf is established. In this study, we have investigated the outermost part of the northeastern Greenland continental shelf. This is the widest shelf surrounding Greenland, with a shelf edge located more than 200 km off the coastline. Here, the shelf morphology comprises two large troughs (Norske Trough and the Westwind Trough) separated by a shallow bank complex (Belgica Bank, Northwind Shoal and the AWI Bank). Previous studies differ strongly on where this sector of the Greenland Ice Sheet reached its maximum position during the LGM. The studies point to positions from the inner shelf, mid-shelf or the shelf edge with the largest uncertainty related to the area of the shallow bank complex. During favorable sea-ice conditions in 2017, a ~130 km2 area on the outermost part of the shelf was surveyed by multi-beam echo-sounder and a sub-bottom profiler (Chirp). Close to the shelf break, the data displays part of a shelf-break parallel ridge that is heavily scoured by icebergs. The ridge is c. 30 m high, up to 9 km wide and with a steep western (proximal) and a gentler eastern (distal) slope. Compared to the recessional moraines reported from elsewhere in this area (Arndt et al., 2017), this feature is wider and higher, and its shape resembles a grounding-zone wedge identified in the nearby Norske Trough. Thus, we tentatively suggest that the observed ridge is also a grounding zone wedge formed at the grounding line of an ice sheet or ice cap reaching the outermost shelf. Part of a second ridge is seen approx. 10 km west of (inside) this ridge, implying a dynamic ice front with several halts or readvances during the retreat from the outer shelf. The age of these features remains to be determined, and this will be part of the future analysis of the sediment cores obtained in the study area. [ABSTRACT FROM AUTHOR]
- Published
- 2019
16. The deglaciation of the NW Barents Sea – new insights from swath-bathymetry and sub-bottom profiler data from east of the Svalbard archipelago.
- Author
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Rydningen, Tom Arne, Eilertsen, Vårin Trælvik, Forwick, Matthias, Husum, Katrine, Lasabuda, Amando, Laberg, Jan Sverre, and Ninnemann, Ulysses Silas
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GLACIAL landforms , *GLACIAL melting , *ICE sheet thawing , *SEA ice , *ICE sheets , *LAST Glacial Maximum - Abstract
With the decay of marine-based ice sheets observed today, e.g. in Antarctica and Greenland, there is a pressing need also for an improved understanding of marine paleo-ice sheets and their decay, as they provide critical constraints for a better understanding of the dynamics of modern ice sheets and their future behavior.Here we present new multi-beam swath-bathymetry and high-resolution Topas seismic data from the NW Barents Sea acquired during the Nansen Legacy (https://arvenetternansen.com/) Paleo-cruise in 2018, which provide new insights on the deglaciation history of the marine based Svalbard-Barents Sea Ice Sheet. Previous multi-beam data from the straits and troughs east of the Svalbard archipelago provided unclear or even conflicting evidence of full-glacial flow; i) eastwards, through the Erik Eriksen Strait and its eastward continuation, terminating in the Franz Victoria Trough, and ii) northwards through the Kvitøya Trough (Dowdeswell et al., 2010; Hogan et al., 2010).The new data provide evidence of a dynamic ice-sheet retreat during the deglaciation of the Erik Eriksen Strait and its eastern extension. A succession of superposing transverse ridges with a zig-zag like morphology characterize the eastern part of the mapped area. These ridges are interpreted to be recessional push-moraines, resulting from several smaller re-advances of the ice front during overall retreat through this part of the strait. To the west, ridges are buried by a ~40 m high and 20 km long sedimentary wedge, characterized by a smooth surface. The internal seismic configuration of the wedge is transparent. This sediment accumulation is interpreted to be a grounding zone wedge that likely formed during a major eastward oriented re-advance of the Svalbard-Barents Sea Ice Sheet during the deglaciation, burying some of the older recessional push-moraines. Thus, the eastward flow previously identified may be due to a major re-advance during the deglaciation rather than formed during full-glacial conditions.A ~3 msec thick layer of acoustically transparent sediments covering the grounding zone wedge and the recessional push-moraines, has been ground-truthed by gravity cores, both in front (east) of, and on top of the wedge. Radiocarbon dating will provide a minimum age for the formation of the glacial landforms, and thus add to our knowledge on the timing and dynamics of the retreat of this marine-based sector of the Svalbard-Barents Sea Ice Sheet following the Last Glacial Maximum, and this will enable improved modelling of this marine-based ice sheet.References:Dowdeswell, J.A., Hogan, K.A., Evans, J., Noormets, R., Ó Cofaigh, C., and Ottesen, D. (2010). Past ice-sheet flow east of Svalbard inferred from streamlined subglacial landforms. Geology, 38(2), 163-166.Hogan, K.A., Dowdeswell, J.A., Noormets, R., Evans, J., Cofaigh, C.Ó., and Jakobsson, M. (2010). Submarine landforms and ice-sheet flow in the Kvitøya Trough, northwestern Barents Sea. Quaternary Science Reviews, 29(25), 3545-3562. [ABSTRACT FROM AUTHOR]
- Published
- 2019
17. Depicting a high-latitude channel system: the INBIS Channel (NW Barents Sea).
- Author
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Rui, Leonardo, Rebesco, Michele, Casamor, José Luis, Laberg, Jan Sverre, Rydningen, Tom Arne, Caburlotto, Andrea, Forwick, Matthias, Urgeles, Roger, Accettella, Daniela, Madrussani, Gianni, Demarte, Maurizio, Ivaldi, Roberta, and Lucchi, Renata Giulia
- Published
- 2018
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