Pattern, style and timing of British–Irish Ice Sheet advance and retreat over the last 45 000 years: evidence from NW Scotland and the adjacent continental shelf

Bradwell, Tom; Fabel, Derek; Clark, Chris D.; Chiverrell, Richard; Small, David; Smedley, Rachel; Saher, Margot; Moreton, Steven Grahame; Dove, Dayton; Callard, S. Louise; Duller, G.A.T.; Medialdea, Alicia; Bateman, Mark D.; Burke, Matthew J.; McDonald, N. Robb; Gilgannon, Sean Michael; Morgan, Sally; Roberts, David H.; Cofaigh, Colm Ó

doi:10.1002/jqs.3296

Cited by 27 publications

(28 citation statements)

References 152 publications

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“…For the former MSIS, the geomorphological evidence shows the presence of a compound ridge close to the shelf edge comprising a series of moraines and grounding‐zone wedges (GZWs) mapped from 55°30′N to 56°30′N (Dunlop et al ., 2010; Callard et al ., 2018). Further to the north, a series of morainal banks with a similar N–S orientation have been broadly mapped from seismic data down to 150 m water depth and are likely to be the continuation of the same ice margin and to be related to the extension of the Outer Hebrides Ice Cap on the Scottish continental shelf (Bradwell et al ., 2021). Moraines of different orientations are observed at the boundary between the DBIS (T6) and MSIS (T7) on the Malin Shelf [trending, respectively NW–SE and NE–SW; Figs.…”

Section: Results and Interpretationsmentioning

confidence: 99%

Exploring controls of the early and stepped deglaciation on the western margin of the British Irish Ice Sheet

Benetti

Chiverrell

Cofaigh

et al. 2021

J Quaternary Science

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New optically stimulated luminescence dating and Bayesian models integrating all legacy and BRITICE‐CHRONO geochronology facilitated exploration of the controls on the deglaciation of two former sectors of the British–Irish Ice Sheet, the Donegal Bay (DBIS) and Malin Sea ice‐streams (MSIS). Shelf‐edge glaciation occurred ~27 ka, before the global Last Glacial Maximum, and shelf‐wide retreat began 26–26.5 ka at a rate of ~18.7–20.7 m a–1. MSIS grounding zone wedges and DBIS recessional moraines show episodic retreat punctuated by prolonged still‐stands. By ~23–22 ka the outer shelf (~25 000 km2) was free of grounded ice. After this time, MSIS retreat was faster (~20 m a–1 vs. ~2–6 m a–1 of DBIS). Separation of Irish and Scottish ice sources occurred ~20–19.5 ka, leaving an autonomous Donegal ice dome. Inner Malin shelf deglaciation followed the submarine troughs reaching the Hebridean coast ~19 ka. DBIS retreat formed the extensive complex of moraines in outer Donegal Bay at 20.5–19 ka. DBIS retreated on land by ~17–16 ka. Isolated ice caps in Scotland and Ireland persisted until ~14.5 ka. Early retreat of this marine‐terminating margin is best explained by local ice loading increasing water depths and promoting calving ice losses rather than by changes in global temperatures. Topographical controls governed the differences between the ice‐stream retreat from mid‐shelf to the coast.

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Section: Results and Interpretationsmentioning

confidence: 99%

Exploring controls of the early and stepped deglaciation on the western margin of the British Irish Ice Sheet

Benetti

Chiverrell

Cofaigh

et al. 2021

J Quaternary Science

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“…Deposition of organic matter in contemporary nearshore glacial settings has been found within the fjords of western Svalbard [37] where gas-charged sediment is observed resulting from organic matter associated with marine productivity distal to the glacial margin. Further examples of biogenic gas accumulations within Late Pleistocene (Weichselian) glaciomarine muds are found in the North Sea Basin [38] and in one or two nearshore basins off northwest Scotland [39][40][41]. Within Loch Linnhe, total carbon content has been estimated at 92.28 Mt [23], but with very low C/N ratios recorded within the uppermost 4 m of sediment [28].…”

Section: Interpretation and Discussionmentioning

confidence: 99%

Spatial Relationships between Pockmarks and Sub-Seabed Gas in Fjordic Settings: Evidence from Loch Linnhe, West Scotland

et al. 2021

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Sub-seabed gas is commonly associated with seabed depressions known as pockmarks—the main venting sites for hydrocarbon gases to enter the water column. Sub-seabed gas accumulations are characterized by acoustically turbid or opaque zones in seismic reflection profiles, taking the form of gas blankets, curtains or plumes. How the migration of sub-seabed gas relates to the origin and distribution of pockmarks in nearshore and fjordic settings is not well understood. Using marine geophysical data from Loch Linnhe, a Scottish fjord, we show that shallow sub-seabed gas occurs predominantly within glaciomarine facies either as widespread blankets in basins or as isolated pockets. We use geospatial ‘hot-spot’ analysis conducted in ArcGIS to identify clusters of pockmarks and acoustic (sub-seabed) profile interpretation to identify the depth to gas front across the fjord. By combining these analyses, we find that the gas below most pockmarks in Loch Linnhe is between 1.4 m and 20 m deep. We anticipate that this work will help to understand the fate and mobility of sedimentary carbon in fjordic (marine) settings and advise offshore industry on the potential hazards posed by pockmarked seafloor regions even in nearshore settings.

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“…Geochronological dates with a quality control rating of Green or Amber by Small et al. (2017) were used, along with additional offshore dates from (Bateman et al., 2018; Bradwell et al., 2021; Callard et al., 2018; Evans et al., 2018, 2019, 2021; Roberts et al., 2018, 2019), resulting in 131 geochronological dates for comparison with modeled deglaciation ages. ATAT calculates the wRMSE between modeled deglaciation ages and geochronological data, accounting for the uneven spatial distribution of dates.…”

Section: Methodsmentioning

confidence: 99%

“…The Automated Timing Accordance Tool (ATAT) (Ely et al, 2019a(Ely et al, , 2019b) is used to identify matches between modeled deglaciation ages and geochronological data (in calibrated years before present). Geochronological dates with a quality control rating of Green or Amber by Small et al (2017) were used, along with additional offshore dates from (Bateman et al, 2018;Bradwell et al, 2021;Callard et al, 2018;Evans et al, 2018Evans et al, , 2019Evans et al, , 2021Roberts et al, 2018Roberts et al, , 2019, resulting in 131 geochronological dates for comparison with modeled deglaciation ages. ATAT calculates the wRMSE between modeled deglaciation ages and geochronological data, accounting for the uneven spatial distribution of dates.…”

Section: Model-data Comparisonmentioning

confidence: 99%

Collapse of the Last Eurasian Ice Sheet in the North Sea Modulated by Combined Processes of Ice Flow, Surface Melt, and Marine Ice Sheet Instabilities

et al. 2021

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The North Sea sector is a shallow marine basin, which is topographically dominated by the Norwegian Channel, a deep (∼200-600 m) trough on the southwestern Norwegian coast (Figure 1). The North Sea sector hosts an archive of palaeo ice sheet dynamics with marine, lacustrine, and terrestrial margins. Therefore, this sector has the potential to provide an analog for contemporary ice sheets and to inform long-term behavior of ice sheets with different marginal settings. For example, the northern marine margin may have been vulnerable to similar marine processes that are in effect in contemporary West Antarctica (Favier et al., 2014;Joughin et al., 2014;Shepherd et al., 2001). These marine sectors are prone to instabilities of retreat, which represent the largest source of uncertainty for future sea level projections (Edwards et al., 2019). Therefore, understanding the deglaciation of marine ice sheet sectors is a key challenge of glaciology. Ice sheet evolution over the North Sea basin is also important in understanding the Relative Sea Level (RSL) change of the basin since the last deglaciation (Bradley et al., 2011). Furthermore, the history of glaciation is a key cause of the complicated stratigraphic record that needs to be understood to plan economically viable offshore wind farm developments in the North Sea (e.g., Emery et al., 2019). All considered, the requirement to better understand the deglaciation of the North Sea sector of the Eurasian Ice Sheet complex has motivated several previous empirical and modeling studies (e.g.

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Pattern, style and timing of British–Irish Ice Sheet advance and retreat over the last 45 000 years: evidence from NW Scotland and the adjacent continental shelf

Cited by 27 publications

References 152 publications

Exploring controls of the early and stepped deglaciation on the western margin of the British Irish Ice Sheet

Exploring controls of the early and stepped deglaciation on the western margin of the British Irish Ice Sheet

Spatial Relationships between Pockmarks and Sub-Seabed Gas in Fjordic Settings: Evidence from Loch Linnhe, West Scotland

Collapse of the Last Eurasian Ice Sheet in the North Sea Modulated by Combined Processes of Ice Flow, Surface Melt, and Marine Ice Sheet Instabilities

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