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5. Growth and retreat of the last British–Irish Ice Sheet, 31 000 to 15 000 years ago: the BRITICE‐CHRONO reconstruction

Author

Clark, Chris D., primary, Ely, Jeremy C., additional, Hindmarsh, Richard C. A., additional, Bradley, Sarah, additional, Ignéczi, Adam, additional, Fabel, Derek, additional, Ó Cofaigh, Colm, additional, Chiverrell, Richard C., additional, Scourse, James, additional, Benetti, Sara, additional, Bradwell, Tom, additional, Evans, David J. A., additional, Roberts, David H., additional, Burke, Matt, additional, Callard, S. Louise, additional, Medialdea, Alicia, additional, Saher, Margot, additional, Small, David, additional, Smedley, Rachel K., additional, Gasson, Edward, additional, Gregoire, Lauren, additional, Gandy, Niall, additional, Hughes, Anna L. C., additional, Ballantyne, Colin, additional, Bateman, Mark D., additional, Bigg, Grant R., additional, Doole, Jenny, additional, Dove, Dayton, additional, Duller, Geoff A. T., additional, Jenkins, Geraint T. H., additional, Livingstone, Stephen L., additional, McCarron, Stephen, additional, Moreton, Steve, additional, Pollard, David, additional, Praeg, Daniel, additional, Sejrup, Hans Petter, additional, Van Landeghem, Katrien J. J., additional, and Wilson, Peter, additional

Published
2022
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8. Growth and retreat of the last British–Irish Ice Sheet, 31 000 to 15 000 years ago: the BRITICE‐CHRONO reconstruction

Author

Clark, Chris D., Ely, Jeremy C., Hindmarsh, Richard C.A., Bradley, Sarah, Ignéczi, Adam, Fabel, Derek, Ó Cofaigh, Colm, Chiverrell, Richard C., Scourse, James, Benetti, Sara, Bradwell, Tom, Evans, David J.A., Roberts, David H., Burke, Matt, Callard, S. Louise, Medialdea, Alicia, Saher, Margot, Small, David, Smedley, Rachel K., Gasson, Edward, Gregoire, Lauren, Gandy, Niall, Hughes, Anna L.C., Ballantyne, Colin, Bateman, Mark D., Bigg, Grant R., Doole, Jenny, Dove, Dayton, Duller, Geoff A.T., Jenkins, Geraint T.H., Livingstone, Stephen L., McCarron, Stephen, Moreton, Steve, Pollard, David, Praeg, Daniel, Sejrup, Hans Petter, Van Landeghem, Katrien J.J., Wilson, Peter, Clark, Chris D., Ely, Jeremy C., Hindmarsh, Richard C.A., Bradley, Sarah, Ignéczi, Adam, Fabel, Derek, Ó Cofaigh, Colm, Chiverrell, Richard C., Scourse, James, Benetti, Sara, Bradwell, Tom, Evans, David J.A., Roberts, David H., Burke, Matt, Callard, S. Louise, Medialdea, Alicia, Saher, Margot, Small, David, Smedley, Rachel K., Gasson, Edward, Gregoire, Lauren, Gandy, Niall, Hughes, Anna L.C., Ballantyne, Colin, Bateman, Mark D., Bigg, Grant R., Doole, Jenny, Dove, Dayton, Duller, Geoff A.T., Jenkins, Geraint T.H., Livingstone, Stephen L., McCarron, Stephen, Moreton, Steve, Pollard, David, Praeg, Daniel, Sejrup, Hans Petter, Van Landeghem, Katrien J.J., and Wilson, Peter

Abstract

The BRITICE-CHRONO consortium of researchers undertook a dating programme to constrain the timing of advance, maximum extent and retreat of the British–Irish Ice Sheet between 31 000 and 15 000 years before present. The dating campaign across Ireland and Britain and their continental shelves, and across the North Sea included 1500 days of field investigation yielding 18 000 km of marine geophysical data, 377 cores of sea floor sediments, and geomorphological and stratigraphical information at 121 sites on land; generating 690 new geochronometric ages. These findings are reported in 28 publications including synthesis into eight transect reconstructions. Here we build ice sheet-wide reconstructions consistent with these findings and using retreat patterns and dates for the inter-transect areas. Two reconstructions are presented, a wholly empirical version and a version that combines modelling with the new empirical evidence. Palaeoglaciological maps of ice extent, thickness, velocity, and flow geometry at thousand-year timesteps are presented. The maximum ice volume of 1.8 m sea level equivalent occurred at 23 ka. A larger extent than previously defined is found and widespread advance of ice to the continental shelf break is confirmed during the last glacial. Asynchrony occurred in the timing of maximum extent and onset of retreat, ranging from 30 to 22 ka. The tipping point of deglaciation at 22 ka was triggered by ice stream retreat and saddle collapses. Analysis of retreat rates leads us to accept our hypothesis that the marine-influenced sectors collapsed rapidly. First order controls on ice-sheet demise were glacio-isostatic loading triggering retreat of marine sectors, aided by glaciological instabilities and then climate warming finished off the smaller, terrestrial ice sheet. Overprinted on this signal were second order controls arising from variations in trough topographies and with sector-scale ice geometric readjustments arising from dispositions in the ge

Published
2022

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

Author

Benetti, Sara, primary, Chiverrell, Richard C., additional, Cofaigh, Colm Ó, additional, Burke, Matt, additional, Medialdea, Alicia, additional, Small, David, additional, Ballantyne, Colin, additional, Bateman, Mark D., additional, Callard, S. Louise, additional, Wilson, Peter, additional, Fabel, Derek, additional, Clark, Chris D., additional, Arosio, Riccardo, additional, Bradley, Sarah, additional, Dunlop, Paul, additional, Ely, Jeremy C., additional, Gales, Jenny, additional, Livingstone, Stephen J., additional, Moreton, Steven G., additional, Purcell, Catriona, additional, Saher, Margot, additional, Schiele, Kevin, additional, Van Landeghem, Katrien, additional, and Weilbach, Kasper, additional

Published
2021
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11. Retreat dynamics of the eastern sector of the British-Irish Ice Sheet during the last glaciation

Author

Evans, David J. A., Roberts, David H., Bateman, Mark D., Clark, Chris D., Medialdea, Alicia, Callard, Louise, Grimoldi, Elena, Chiverrell, Richard C., Ely, Jeremy, Dove, Dayton, Cofaigh, Colm O., Saher, Margot, Bradwell, Tom, Moreton, Steven G., Fabel, Derek, Bradley, Sarah L., Evans, David J. A., Roberts, David H., Bateman, Mark D., Clark, Chris D., Medialdea, Alicia, Callard, Louise, Grimoldi, Elena, Chiverrell, Richard C., Ely, Jeremy, Dove, Dayton, Cofaigh, Colm O., Saher, Margot, Bradwell, Tom, Moreton, Steven G., Fabel, Derek, and Bradley, Sarah L.

Abstract

The findings of BRITICE-CHRONO Transect 2 through the North Sea Basin and eastern England are reported. We define ice-sheet marginal oscillation between -31 and 16 ka, with seven distinctive former ice-sheet limits (L1-7) constrained by Bayesian statistical analysis. The southernmost limit of the North Sea Lobe is recorded by the Bolders Bank Formation (L1; 25.8-24.6 ka). L2 represents ice-sheet oscillation and early retreat to the northern edge of the Dogger Bank (23.5-22.2 ka), with the Garret Hill Moraine in north Norfolk recording a significant regional readvance to L3 at 21.5-20.8 ka. Ice-marginal oscillations at similar to 26-21 ka resulted in L1, L2 and L3 being partially to totally overprinted. Ice-dammed lakes related to L1-3, including Lake Humber, are dated at 24.1-22.3 ka. Ice-sheet oscillation and retreat from L4 to L5 occurred between 19.7 and 17.3 ka, with grounding zone wedges marking an important transition from terrestrial to marine tidewater conditions, triggered by the opening of the Dogger Lake spillway between 19.9 and 17.5 ka. L6 relates to ice retreat under glacimarine conditions and final ice retreat into the Firth of Forth by 15.8 ka. L7 (-15 ka) represents an ice retreat from Bosies Bank into the Moray Firth. Copyright (C) 2021 The Authors Journal of Quaternary Science Published by John Wiley & Sons Ltd

Published
2021

12. 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

Author

Bradwell, Tom, Fabel, Derek, Clark, Chris D., Chiverrell, Richard C., Small, David, Smedley, Rachel K., Saher, Margot H., Moreton, Steven G., Dove, Dayton, Callard, S. Louise, Duller, Geoff A. T., Medialdea, Alicia, Bateman, Mark D., Burke, Matthew J., McDonald, Neil, Gilgannon, Sean, Morgan, Sally, Roberts, David H., Cofaigh, Colm ó, Bradwell, Tom, Fabel, Derek, Clark, Chris D., Chiverrell, Richard C., Small, David, Smedley, Rachel K., Saher, Margot H., Moreton, Steven G., Dove, Dayton, Callard, S. Louise, Duller, Geoff A. T., Medialdea, Alicia, Bateman, Mark D., Burke, Matthew J., McDonald, Neil, Gilgannon, Sean, Morgan, Sally, Roberts, David H., and Cofaigh, Colm ó

Abstract

Predicting the future response of ice sheets to climate warming and rising global sea level is important but difficult. This is especially so when fast‐flowing glaciers or ice streams, buffered by ice shelves, are grounded on beds below sea level. What happens when these ice shelves are removed? And how do the ice stream and the surrounding ice sheet respond to the abruptly altered boundary conditions? To address these questions and others we present new geological, geomorphological, geophysical and geochronological data from the ice‐stream‐dominated NW sector of the last British–Irish Ice Sheet (BIIS). The study area covers around 45 000 km2 of NW Scotland and the surrounding continental shelf. Alongside seabed geomorphological mapping and Quaternary sediment analysis, we use a suite of over 100 new absolute ages (including cosmogenic‐nuclide exposure ages, optically stimulated luminescence ages and radiocarbon dates) collected from onshore and offshore, to build a sector‐wide ice‐sheet reconstruction combining all available evidence with Bayesian chronosequence modelling. Using this information we present a detailed assessment of ice‐sheet advance/retreat history, and the glaciological connections between different areas of the NW BIIS sector, at different times during the last glacial cycle. The results show a highly dynamic, partly marine, partly terrestrial, ice‐sheet sector undergoing large size variations in response to sub‐millennial‐scale climatic (Dansgaard–Oeschger) cycles over the last 45 000 years. Superimposed on these trends we identify internally driven instabilities, operating at higher frequency, conditioned by local topographic factors, tidewater dynamics and glaciological feedbacks during deglaciation. Specifically, our new evidence indicates extensive marine‐terminating ice‐sheet glaciation of the NW BIIS sector during Greenland Stadials 12 to 9 – prior to the main ‘Late Weichselian’ ice‐sheet glaciation. After a period of restricted glaciation

Published
2021

13. Pattern, style and timing of British–Irish Ice Sheet retreat: Shetland and northern North Sea sector

Author

Bradwell, Tom, Small, David, Fabel, Derek, Clark, Chris D., Chiverrell, Richard C., Saher, Margot H., Dove, Dayton, Callard, S. Louise, Burke, Matthew J., Moreton, Steven G., Medialdea, Alicia, Bateman, Mark D., Roberts, David H., Golledge, Nicholas R., Finlayson, Andrew, Morgan, Sally, Cofaigh, Colm Ó, Bradwell, Tom, Small, David, Fabel, Derek, Clark, Chris D., Chiverrell, Richard C., Saher, Margot H., Dove, Dayton, Callard, S. Louise, Burke, Matthew J., Moreton, Steven G., Medialdea, Alicia, Bateman, Mark D., Roberts, David H., Golledge, Nicholas R., Finlayson, Andrew, Morgan, Sally, and Cofaigh, Colm Ó

Abstract

The offshore sector around Shetland remains one of the least well‐studied parts of the former British–Irish Ice Sheet with several long‐standing scientific issues unresolved. These key issues include (i) the dominance of a locally sourced ‘Shetland ice cap’ vs an invasive Fennoscandian Ice Sheet; (ii) the flow configuration and style of glaciation at the Last Glacial Maximum (i.e. terrestrial vs marine glaciation); (iii) the nature of confluence between the British–Irish and Fennoscandian Ice Sheets; (iv) the cause, style and rate of ice sheet separation; and (v) the wider implications of ice sheet uncoupling on the tempo of subsequent deglaciation. As part of the Britice‐Chrono project, we present new geological (seabed cores), geomorphological, marine geophysical and geochronological data from the northernmost sector of the last British–Irish Ice Sheet (north of 59.5°N) to address these questions. The study area covers ca. 95 000 km2, an area approximately the size of Ireland, and includes the islands of Shetland and the surrounding continental shelf, some of the continental slope, and the western margin of the Norwegian Channel. We collect and analyse data from onshore in Shetland and along key transects offshore, to establish the most coherent picture, so far, of former ice‐sheet deglaciation in this important sector. Alongside new seabed mapping and Quaternary sediment analysis, we use a multi‐proxy suite of new isotopic age assessments, including 32 cosmogenic‐nuclide exposure ages from glacially transported boulders and 35 radiocarbon dates from deglacial marine sediments, to develop a synoptic sector‐wide reconstruction combining strong onshore and offshore geological evidence with Bayesian chronosequence modelling. The results show widespread and significant spatial fluctuations in size, shape and flow configuration of an ice sheet/ice cap centred on, or to the east of, the Orkney–Shetland Platform, between ~30 and ~15 ka BP. At its maximum extent ca. 26–25

Published
2021

14. Timing and pace of ice‐sheet withdrawal across the marine–terrestrial transition west of Ireland during the last glaciation

Author

Ó Cofaigh, Colm, Callard, S. Louise, Roberts, David H., Chiverrell, Richard C., Ballantyne, C. K., Evans, David J. A., Saher, Margot, Van Landeghem, Katrien J. J., Smedley, Rachel, Benetti, Sara, Burke, Matthew, Clark, Chris D., Duller, Geoff A. T., Fabel, Derek, Livingstone, Stephen J., Mccarron, Stephen, Medialdea, Alicia, Moreton, Steven G., Sacchetti, Fabio, Ó Cofaigh, Colm, Callard, S. Louise, Roberts, David H., Chiverrell, Richard C., Ballantyne, C. K., Evans, David J. A., Saher, Margot, Van Landeghem, Katrien J. J., Smedley, Rachel, Benetti, Sara, Burke, Matthew, Clark, Chris D., Duller, Geoff A. T., Fabel, Derek, Livingstone, Stephen J., Mccarron, Stephen, Medialdea, Alicia, Moreton, Steven G., and Sacchetti, Fabio

Abstract

Understanding the pace and drivers of marine‐based ice‐sheet retreat relies upon the integration of numerical ice‐sheet models with observations from contemporary polar ice sheets and well‐constrained palaeo‐ glaciological reconstructions. This paper provides a reconstruction of the retreat of the last British–Irish Ice Sheet (BIIS) from the Atlantic shelf west of Ireland during and following the Last Glacial Maximum (LGM). It uses marine‐ geophysical data and sediment cores dated by radiocarbon, combined with terrestrial cosmogenic nuclide and optically stimulated luminescence dating of onshore ice‐marginal landforms, to reconstruct the timing and rate of ice‐sheet retreat from the continental shelf and across the adjoining coastline of Ireland, thus including the switch from a marine‐ to a terrestrially‐based ice‐sheet margin. Seafloor bathymetric data in the form of moraines and grounding‐zone wedges on the continental shelf record an extensive ice sheet west of Ireland during the LGM which advanced to the outer shelf. This interpretation is supported by the presence of dated subglacial tills and overridden glacimarine sediments from across the Porcupine Bank, a westwards extension of the Irish continental shelf. The ice sheet was grounded on the outer shelf at ~26.8 ka cal BP with initial retreat underway by 25.9 ka cal BP. Retreat was not a continuous process but was punctuated by marginal oscillations until ~24.3 ka cal BP. The ice sheet thereafter retreated to the mid‐shelf where it formed a large grounding‐zone complex at ~23.7 ka cal BP. This retreat occurred in a glacimarine environment. The Aran Islands on the inner continental shelf were ice‐free by ~19.5 ka BP and the ice sheet had become largely terrestrially based by 17.3 ka BP. This suggests that the Aran Islands acted to stabilize and slow overall ice‐sheet retreat once the BIIS margin had reached the inner shelf. Our results constrain the timing of initial retreat of the BIIS from the outer shelf w

Published
2021

15. Timing and pace of ice‐sheet withdrawal across the marine–terrestrial transition west of Ireland during the last glaciation

Author

Ó Cofaigh, Colm, primary, Callard, S. Louise, additional, Roberts, David H., additional, Chiverrell, Richard C., additional, Ballantyne, C. K., additional, Evans, David J. A., additional, Saher, Margot, additional, Van Landeghem, Katrien J. J., additional, Smedley, Rachel, additional, Benetti, Sara, additional, Burke, Matthew, additional, Clark, Chris D., additional, Duller, Geoff A. T., additional, Fabel, Derek, additional, Livingstone, Stephen J., additional, Mccarron, Stephen, additional, Medialdea, Alicia, additional, Moreton, Steven G., additional, and Sacchetti, Fabio, additional

Published
2021
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16. 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

Author

Bradwell, Tom, primary, Fabel, Derek, additional, Clark, Chris D., additional, Chiverrell, Richard C., additional, Small, David, additional, Smedley, Rachel K., additional, Saher, Margot H., additional, Moreton, Steven G., additional, Dove, Dayton, additional, Callard, S. Louise, additional, Duller, Geoff A. T., additional, Medialdea, Alicia, additional, Bateman, Mark D., additional, Burke, Matthew J., additional, McDonald, Neil, additional, Gilgannon, Sean, additional, Morgan, Sally, additional, Roberts, David H., additional, and Cofaigh, Colm ó, additional

Published
2021
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17. Retreat dynamics of the eastern sector of the British–Irish Ice Sheet during the last glaciation

Author

Evans, David J. A., primary, Roberts, David H., additional, Bateman, Mark D., additional, Clark, Chris D., additional, Medialdea, Alicia, additional, Callard, Louise, additional, Grimoldi, Elena, additional, Chiverrell, Richard C., additional, Ely, Jeremy, additional, Dove, Dayton, additional, Ó Cofaigh, Colm, additional, Saher, Margot, additional, Bradwell, Tom, additional, Moreton, Steven G., additional, Fabel, Derek, additional, and Bradley, Sarah L., additional

Published
2021
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18. A preindustrial sea-level rise hotspot along the Atlantic Coast of North America

Author

Gehrels, W. Roland, Dangendorf, Sönke, Barlow, Natasha L. M., Saher, Margot H., Long, Antony J., Woodworth, Philip L., Piecuch, Christopher G., Berk, Kevin, Gehrels, W. Roland, Dangendorf, Sönke, Barlow, Natasha L. M., Saher, Margot H., Long, Antony J., Woodworth, Philip L., Piecuch, Christopher G., and Berk, Kevin

Abstract

© The Author(s), 2020. This article is distributed under the terms of the Creative Commons Attribution License. The definitive version was published in Gehrels, W. R., Dangendorf, S., Barlow, N. L. M., Saher, M. H., Long, A. J., Woodworth, P. L., Piecuch, C. G., & Berk, K. A preindustrial sea-level rise hotspot along the Atlantic Coast of North America. Geophysical Research Letters, 47(4), (2020): e2019GL085814, doi:10.1029/2019GL085814., The Atlantic coast of North America north of Cape Hatteras has been proposed as a “hotspot” of late 20th century sea‐level rise. Here we test, using salt‐marsh proxy sea‐level records, if this coast experienced enhanced sea‐level rise over earlier multidecadal‐centennial periods. While we find in agreement with previous studies that 20th century rates of sea‐level change were higher compared to rates during preceding centuries, rates of 18th century sea‐level rise were only slightly lower, suggesting that the “hotspot” is a reoccurring feature for at least three centuries. Proxy sea‐level records from North America (Iceland) are negatively (positively) correlated with centennial changes in the North Atlantic Oscillation. They are consistent with sea‐level “fingerprints” of Arctic ice melt, and we therefore hypothesize that sea‐level fluctuations are related to changes in Arctic land‐ice mass. Predictions of future sea‐level rise should take into account these long‐term fluctuating rates of natural sea‐level change., This work is funded by the Natural Environment Research Council (grant NE/G003440/1). All radiocarbon dating was supported by the Natural Environment Research Council Radiocarbon Facility (allocations 1490.0810, 1566.0511, 1604.0112). Mark Wood assisted with fieldwork. Rob Scaife analyzed pollen data for core SN‐3.3. Sönke Dangendorf and Kevin Berk acknowledge the University of Siegen for their support within the PEPSEA project. Christopher Piecuch was supported by National Science Foundation awards OCE‐1558966 and OCE‐1834739. We thank project members Miguel Ángel Morales Maqueda, Chris Hughes, Vassil Roussenov and Ric Williams for valuable discussions. We are grateful to the International Space Science Institute (ISSI; Bern, Switzerland) for support of the International Team “Towards a unified Sea Level Record”. Data used in this paper are freely available online (https://www.doi.org/10/dgvq).

Published
2020

19. The advance and retreat of the Irish Sea Ice Stream in the Celtic Sea and its influence on shelf evolution

Author

Lockhart, Edward, Scourse, James, Praeg, D, van Landeghem, Katrien J.J., Mellett, Claire, Saher, Margot, Callard, Louise, Chiverrell, Richard C., Benetti, Sara, Cofaigh, Colm Ó, Clark, Chris, School of Ocean Sciences [Menai Bridge], Bangor University, University of Exeter, Géoazur (GEOAZUR 7329), Institut national des sciences de l'Univers (INSU - CNRS)-Observatoire de la Côte d'Azur, COMUE Université Côte d'Azur (2015-2019) (COMUE UCA)-Université Côte d'Azur (UCA)-COMUE Université Côte d'Azur (2015-2019) (COMUE UCA)-Université Côte d'Azur (UCA)-Centre National de la Recherche Scientifique (CNRS)-Institut de Recherche pour le Développement (IRD [France-Sud]), Istituto Nazionale di Geofisica e di Oceanografia Sperimentale (OGS), Wessex Archaeology [Salisbury], Department of Geography (UNIVERSITé DE DURHAM), Durham University, University of Liverpool, School of Geography and Environmental Sciences, University of Ulster, Department of Geography [Sheffield], University of Sheffield [Sheffield], European Project: 656821,H2020,H2020-MSCA-IF-2014,SEAGAS(2016), School of Ocean Sciences [Bangor], Université Côte d'Azur (UCA)-Université Côte d'Azur (UCA)-Centre National de la Recherche Scientifique (CNRS)-Institut de Recherche pour le Développement (IRD [France-Sud]), Université Côte d'Azur (UCA)-COMUE Université Côte d'Azur (2015-2019) (COMUE UCA)-Université Côte d'Azur (UCA)-COMUE Université Côte d'Azur (2015-2019) (COMUE UCA)-Centre National de la Recherche Scientifique (CNRS)-Institut de Recherche pour le Développement (IRD [France-Sud]), Daniel, Praeg, and Multi-disciplinary Comparison of Fluid Venting from Gas Hydrate Systems on the Mediterranean and Brazilian Continental Margins over Glacial-Interglacial Timescales - SEAGAS - - H20202016-04-30 - 2019-04-29 - 656821 - VALID

Subjects
[SDU.STU.GM] Sciences of the Universe [physics]/Earth Sciences/Geomorphology, [SDU.STU.ST]Sciences of the Universe [physics]/Earth Sciences/Stratigraphy, [SDU.STU] Sciences of the Universe [physics]/Earth Sciences, [SDU.STU.ST] Sciences of the Universe [physics]/Earth Sciences/Stratigraphy, [SDU.STU]Sciences of the Universe [physics]/Earth Sciences, [SDU.STU.GL]Sciences of the Universe [physics]/Earth Sciences/Glaciology, [SDU.STU.GM]Sciences of the Universe [physics]/Earth Sciences/Geomorphology, [SDU.STU.OC] Sciences of the Universe [physics]/Earth Sciences/Oceanography, [SDU.STU.OC]Sciences of the Universe [physics]/Earth Sciences/Oceanography, [SDU.STU.GL] Sciences of the Universe [physics]/Earth Sciences/Glaciology
Abstract

International audience; The reconstruction of the largest ice stream to drain the British-Irish Ice Sheet at the Last Glacial Maximum (LGM) can provide essential palaeoglacial observations required for constraining numerical ice sheet models. The Irish Sea Ice Stream (ISIS) was long considered to have terminated on the mid-shelf of the Celtic Sea, based on sediment cores and seismic data collected in the 1970s. Here we summarise findings from sediment cores and geophysical data acquired since 2009, and multi-beam bathymetric data acquired since 2001, which permit an updated evolution and palaeoglacial reconstruction of the Irish and UK sectors of the Celtic Sea shelf. In near-shore areas, multi-beam data reveal over 2000 glacial features, including moraine ridges, streamlined bedrock and meltwater channels, recording the southwest advance of the ISIS towards the shelf-edge and its subsequent retreat. The mid- to outer-shelf is characterised by the largest known linear shelf sediment ridges. These vary from long and linear features, the megaridges, in the northwest to sinuous and shorter ridges in the southeast. This ridge field was initially interpreted as tidal in origin, but glacigenic sediments have been recovered from the flanks of the megaridges. Correlating decimetric-resolution geophysical data to sediment cores, the megaridges comprise three main units. 1) A superficial fining-upward drape above an unconformity, inferred to record decreasing ocean energy during marine transgression. Underlying this drape is 2), the Melville Formation (MFm), which comprises the upper bulk of the megaridges, displaying dipping internal acoustic reflections and consisting of medium to coarse sand and gravel, characteristics that could be consistent with either a tidal or glacifluvial origin. The MFm unconformably overlies 3), the Upper Little Sole Formation (ULSFm), previously proposed to be of late Pliocene to early Pleistocene age, but is here shown to contain glacigenic sediments dated to the LGM. This stratigraphy constrains the age of the MFm to between 24-14 ka BP, coeval with deglaciation and a modelled period of megatidal conditions during transgression. Stratigraphically and sedimentologically these megaridges could represent glacifluvial features eroded during the post-glacial marine transgression. However, it is argued that they comprise a partially-eroded glacial topography (ULSFm) mantled by post-glacial tidal deposits (MFm), both subsequently eroded by a proposed mechanism of enhanced wave energy during decreasing tidal energy in the later stages of transgression. Regardless of the origin of the ridges, the evidence shows that the ISIS extended to the shelf-edge of the Irish and UK sectors during the LGM.

Published
2019

20. Maximum extent and readvance dynamics of the Irish Sea Ice Stream since the Last Glacial Maximum

Author

Scourse, James, Chiverrell, Richard C., SMALL, DAVID, Smedley, Rachel, Medialdea, Alicia, Burke, Matt, Saher, Margot, Callard, Louise, Van Landeghem, Katrien J.J., Duller, Geoff, Fabel, Derek, Moreton, Steve, Lockhart, Edward, Jenkins, Geraint, Praeg, D, Bateman, Mark, Evans, David, Roberts, Dave, McCarron, Stephen, Wilson, Peter, Livingstone, Stephen, Clark, Chris, University of Liverpool, Durham University, University of Sheffield [Sheffield], School of Ocean Sciences [Menai Bridge], Bangor University, Department of Geography (UNIVERSITé DE DURHAM), Aberystwyth University, University of Glasgow, Géoazur (GEOAZUR 7329), Institut national des sciences de l'Univers (INSU - CNRS)-Observatoire de la Côte d'Azur, COMUE Université Côte d'Azur (2015-2019) (COMUE UCA)-Université Côte d'Azur (UCA)-COMUE Université Côte d'Azur (2015-2019) (COMUE UCA)-Université Côte d'Azur (UCA)-Centre National de la Recherche Scientifique (CNRS)-Institut de Recherche pour le Développement (IRD [France-Sud]), Universidade Federal Fluminense [Rio de Janeiro] (UFF), Department of Geography [Sheffield], Department of Geography [Maynooth], National University of Ireland Maynooth (Maynooth University), University of Ulster, European Project: 656821,H2020,H2020-MSCA-IF-2014,SEAGAS(2016), International Union for Quaternary Research (20th Congress), School of Ocean Sciences [Bangor], Université Côte d'Azur (UCA)-Université Côte d'Azur (UCA)-Centre National de la Recherche Scientifique (CNRS)-Institut de Recherche pour le Développement (IRD [France-Sud]), and National University of Ireland Maynooth (NUIM)

Subjects
[SDU.STU.ST]Sciences of the Universe [physics]/Earth Sciences/Stratigraphy, [SDU.STU]Sciences of the Universe [physics]/Earth Sciences, [SDU.STU.GL]Sciences of the Universe [physics]/Earth Sciences/Glaciology, [SDU.STU.GM]Sciences of the Universe [physics]/Earth Sciences/Geomorphology
Abstract

International audience; The Irish Sea Ice Stream (ISIS) has long had one of the best documented retreat histories of the British-Irish Ice Sheet (BIIS) and was the first ice stream to be constrained by Bayesian analysis of geochronological data. These attributes made it a model system for the BRITICE-CHRONO research project, which aims to produce the best constrained retreat record of any palaeo-ice sheet contributing key observational constraints for ice sheet modelling. The project has generated a suite of new radiocarbon ages from deglacial sequences offshore in the Celtic and Irish seas and terrestrial cosmogenic nuclide and optically-stimulated luminescence ages from ice-marginal sites in the Isles of Scilly, Ireland, Wales and NW England. The ISIS was unusual within the former BIIS, in that it was a compound ice stream with two outlets, one marine terminating that flowed through the Irish Sea Basin into the Celtic Sea, and a terrestrial terminus that flowed southwards through Cheshire-Shropshire lowlands into the English Midlands around 25.5 ka. Here we assess the retreat dynamics across the entirety of the ISIS, integrating the new chronology in a revised Bayesian analysis that constrains the pattern and timing ice marginal fluctuations. The retreat chronology in the Irish Sea is better constrained than in the Celtic Sea, where the ISIS is now recognised to have extended as far as the continental shelf break to the SW of Britain and Ireland between 24 and 27 ka; this advance was synchronous with independently-dated ice-rafted detritus from ISIS in adjacent deep-sea cores. The ISIS then retreated rapidly northwards through the Celtic Sea, with evidence for readvance phases, deglaciating the Isles of Scilly at 25.5 ka, reaching St Georges Channel by 24.3 ka and the Llŷn Peninsula by 23.9 ka. The initiation of retreat from both the eastern (terrestrial) and western (marine) components of ISIS was synchronous. The eastern terrestrial lobe had vacated the Cheshire-Shropshire lowlands by 22-21 ka. The complex readvance sequences identified on the Llŷn (24-20ka) and in eastern Ireland have now been tightly constrained to register centennial-scale oscillations of the ice front driven by internal ice dynamics over topographic pinning points and constrictions of the ice-stream. Retreat northwards into the northern Irish Sea then accelerated, first evacuating the deeper water of the western Irish Sea, and developing pronounced ice margins across the northern Isle of Man by 19.1 ka. The final retreat phase, with ice margins pulling back onto terrestrial settings in the English Lake District, the north of Ireland and SW Scotland around 17 ka, was a deglaciation accomplished in a fully marine context evidenced by the preservation on the seabed of subglacial landforms and by increasing influence of local ice sources with flow realignment during draw-down and ice margin retreat.

Published
2019

21. Early deglaciation of the British-Irish Ice Sheet on the Atlantic shelf northwest of Ireland driven by glacioisostatic depression and high relative sea level

Author

Ó Cofaigh, Colm, Weilbach, Kasper, Lloyd, Jerry M., Benetti, Sara, Callard, S. Louise, Purcell, Catriona, Chiverrell, Richard C., Dunlop, Paul, Saher, Margot, Livingstone, Stephen J., Van Landeghem, Katrien J.J., Moreton, Steven G., Clark, Chris D., and Fabel, Derek

Abstract

© 2019 Elsevier Ltd Understanding the triggers and pace of marine-based ice sheet decay is critical for constraining the future mass loss and dynamic behaviour of marine-based sectors of the large polar ice sheets in Greenland and Antarctica. Numerical models which seek to predict this behaviour need to be calibrated against data from both contemporary and palaeo-ice sheets, and the latter requires accurate reconstruction of former ice sheet extent, dynamics and timing. Marine geophysics, sediment cores, benthic foraminiferal assemblages and radiocarbon dating are used to reconstruct the extent of the last British-Irish Ice Sheet (BIIS), and the timing and style of its retreat on the Atlantic shelf northwest of Ireland. Shelf edge moraines and subglacial till recovered in cores from the outer continental shelf are dated to younger than 26.3 ka cal BP and indicate an extensive ice sheet at the Last Glacial Maximum (LGM) that was grounded to the shelf edge. Nested arcuate moraines record the subsequent episodic retreat of the ice sheet across the shelf. Lithofacies and associated foraminiferal assemblages demonstrate that this retreat occurred in a glacimarine environment as a grounded tidewater margin and that high relative sea level and cold waters prevailed during retreat. Radiocarbon dates indicate that the timing of initial ice sheet retreat from the shelf edge occurred in the interval between 26.3 and 24.8 ka cal BP, during the period of minimum global eustatic sea level, and that the ice sheet had retreated to the mid-shelf by 24.8 ka cal BP. The ‘Donegal Bay Moraine’, a large moraine at the mouth of Donegal Bay, records a major stillstand and readvance of the ice sheet during deglaciation between 20.2 and 17.9 ka cal BP. Estimated retreat rates of 5.5–35 m a −1 across the shelf demonstrate that retreat was slow. It is noteworthy that retreat was initiated in the absence of ocean warming and when eustatic sea level was at a minimum. The sea-level rise that initiated deglaciation from the shelf edge therefore, is inferred to have been a product of local glacio-isostatic crustal depression rather than external forcing. This demonstrates that marine-based sectors of ice sheets can trigger their own demise internally through glacio-isostatic adjustment and it provides an explanation for the early retreat of the BIIS on the Atlantic shelf during the global LGM (gLGM).

Published
2019

22. Extent and retreat history of the Barra Fan Ice Stream offshore western Scotland and northern Ireland during the last glaciation

Author

Callard, S. Louise, Ó Cofaigh, Colm, Benetti, Sarah, Chiverrell, Richard C., Van Landeghem, Katrien J.J., Saher, Margot H., Gales, Jenny A., Small, David, Clark, Chris D., Livingstone, Stephen J., Fabel, Derek, and Moreton, Steven G.

Subjects
Radiocarbon dating, Glacimarine, Grounding-zone wedges, Last glacial maximum, Ice-sheet retreat, British-Irish Ice Sheet
Abstract

During the Last Glacial Maximum (LGM) the marine-terminating Barra Fan Ice Stream (BFIS), a major conduit of the British Irish Ice Sheet (BITS), drained much of western Scotland and northwest Ireland with ice streaming onto the continental shelf of the Malin Sea. The extent and retreat history of this ice stream across the shelf, until now, is not well known. In particular, geochronological constraints on the history of this ice stream have thus far been restricted to deep-sea cores or terrestrial cosmogenic nuclide dating onshore, with ages across the shelf absent. To understand the possible external forcing factors acting on this marine terminating ice stream during retreat, improved geochronological constraint on its deglaciation is necessary. Here, we present new geophysical data, marine sediment cores and over forty radiocarbon dates to provide important constraints on maximum extent of the BFIS, as well as the timing and pattern of retreat back across the Malin Shelf. Dated moraines and grounding-zone wedges (GZW) seen in seafloor sub-bottom profiles provide evidence that the BFIS reached the Malin Shelf edge during the LGM and was at its maximum extent around 26.7 ka BP. The presence of two sets of GZWs suggests that the style of retreat was episodic. The new radiocarbon chronology shows that retreat from the shelf edge was underway by 25.9 ka BP, with the majority of the continental shelf ice free by 23.2 ka BP, and that glacimarine conditions were present in the Sea of Hebrides by 20.2 ka BP at the latest. Collectively, these results indicate that the majority of the Malin Shelf was free of grounded ice by similar to 21.5-20 ka BP, which is up to 4000 years earlier than previously reconstructed. We attribute this early deglaciation to high relative sea level caused by glacial isostatic depression when the BIIS reached its maximum extent promoting ice shelf and grounding line instability. Two deep troughs, forming reverse bed slopes, aided the continued retreat of the BFIS. This suggests that local ice loading and bed morphology can be significant controls on the destabilisation of a marine-terminating ice stream and can override the influence of ocean and atmospheric temperatures.

Published
2018

23. The mixed-bed glacial landform imprint of the North Sea Lobe in the western North Sea

Author

Roberts, David H., Grimoldi, Elena, Callard, Louise, Evans, David J. A., Clark, Chris D., Stewart, Heather A., Dove, Dayton, Saher, Margot, Cofaigh, Colm O., Chiverrell, Richard C., Bateman, Mark D., Moreton, Steven G., Bradwell, Tom, Fabel, Derek, Medialdea, Alicia, Roberts, David H., Grimoldi, Elena, Callard, Louise, Evans, David J. A., Clark, Chris D., Stewart, Heather A., Dove, Dayton, Saher, Margot, Cofaigh, Colm O., Chiverrell, Richard C., Bateman, Mark D., Moreton, Steven G., Bradwell, Tom, Fabel, Derek, and Medialdea, Alicia

Abstract

During the last glacial cycle an intriguing feature of the British-Irish Ice Sheet was the North Sea Lobe (NSL); fed from the Firth of Forth and which flowed south and parallel to the English east coast. The controls on the formation and behaviour of the NSL have long been debated, but in the southern North Sea recent work suggests the NSL formed a dynamic, oscillating terrestrial margin operating over a deforming bed. Further north, however, little is known of the behaviour of the NSL or under what conditions it operated. This paper analyses new acoustic, sedimentary and geomorphic data in order to evaluate the glacial landsystem imprint and deglacial history of the NSL offshore from NE England. Subglacial tills (AF2/3) form a discontinuous mosaic interspersed with bedrock outcrops across the seafloor, with the partial excavation and advection of subglacial sediment during both advance and retreat producing mega-scale glacial lineations and grounding zone wedges. The resultant 'mixed-bed' glacial landsystem is the product of a dynamic switch from a terrestrial piedmont-lobe margin with a net surplus of sediment to a partially erosive, quasi-stable, marine-terminating, ice stream lobe as the NSL withdrew northwards. Glaciomarine sediments (AF4) drape the underlying subglacial mixed-bed imprint and point to a switch to tidewater conditions between 19.9 and 16.5 ka cal BP as the North Sea became inundated. The dominant controls on NSL recession during this period were changing ice flux through the Firth of Forth ice stream onset zone and water depths at the grounding line; the development of the mixed-bed landsystem being a response to grounding line instability. (c) 2018 John Wiley & Sons, Ltd.

Published
2019

24. Ice-stream demise dynamically conditioned by trough shape and bed strength

Author

Bradwell, Tom, Small, David, Fabel, Derek, Smedley, Rachel K., Clark, Chris D., Saher, Margot H., Callard, S. Louise, Chiverrell, Richard C., Dove, Dayton, Moreton, Steven G., Roberts, David H., Duller, Geoff A. T., Ó Cofaigh, Colm, Bradwell, Tom, Small, David, Fabel, Derek, Smedley, Rachel K., Clark, Chris D., Saher, Margot H., Callard, S. Louise, Chiverrell, Richard C., Dove, Dayton, Moreton, Steven G., Roberts, David H., Duller, Geoff A. T., and Ó Cofaigh, Colm

Abstract

Ice sheet mass loss is currently dominated by fast-flowing glaciers (ice streams) terminating in the ocean as ice shelves and resting on beds below sea level. The factors controlling ice-stream flow and retreat over longer time scales (>100 years), especially the role of three-dimensional bed shape and bed strength, remain major uncertainties. We focus on a former ice stream where trough shape and bed substrate are known, or can be defined, to reconstruct ice-stream retreat history and grounding-line movements over 15 millennia since the Last Glacial Maximum. We identify a major behavioral step change around 18,500 to 16,000 years ago—out of tune with external forcing factors—associated with the collapse of floating ice sectors and rapid ice-front retreat. We attribute this step change to a marked geological transition from a soft/weak bed to a hard/strong bed coincident with a change in trough geometry. Both these factors conditioned and ultimately hastened ice-stream demise.

Published
2019

25. Ice marginal dynamics of the last British-Irish Ice Sheet in the southern North Sea: Ice limits, timing and the influence of the Dogger Bank

Author

Roberts, David H., Evans, David J.A., Callard, S. Louise, Clark, Chris D., Bateman, Mark D., Medialdea, Alicia, Dove, Dayton, Cotterill, Carol J., Saher, Margot, Cofaigh, Colm Ó, Chiverrell, Richard C., Moreton, Steven G., Fabel, Derek, and Bradwell, Tom

Abstract

The southern North Sea is a particularly important area for understanding the behaviour of the British-Irish Ice Sheet (BIIS) during the last glacial cycle. It preserves a record of the maximum extent of the eastern sector of the BIIS as well as evidence for multiple different ice flow phases and the dynamic re-organisation of the BIIS. However, to date, the known ice sheet history and geochronology of this region is predominantly derived from onshore geological evidence, and the offshore imprint and dynamic history of the last ice sheet remain largely unknown. Using new data collected by the BRITICE-CHRONO project this paper explores the origin and age of the Dogger Bank; re-assesses the extent and age of the glaciogenic deposits across the shallow areas of the North Sea between the Dogger Bank and the north Norfolk coast and; re-examines the dynamic behaviour of the BIIS in the southern North Sea between 31.6 and 21.5 ka.\ud \ud This paper shows the core of the Dogger Bank to be composed glaciolacustrine sediment deposited between 31.6 and 25.8 ka. Following its formation the western end of the Dogger lake was overridden with ice reaching ∼54°N where the ice margin is co-incident with the southerly extent of subglacial tills previously mapped as Bolders Bank Fm. This initial ice override and retreat northwards back across the Dogger lake was complete by 23.1 ka, but resulted in widespread compressive glaciotectonism of the lake sediments and the formation of thrust moraine complexes. Along the northern edge of the bank moraines are on-lapped by later phase glaciolacustrine and marine sediments but do not show evidence of subsequent ice override.\ud \ud The shallow seafloor to the west and southwest of the Dogger Bank records several later phases of ice advance and retreat as the North Sea Lobe flowed between the Dogger Bank and the Yorkshire/Lincolnshire coasts and reached North Norfolk. New optically stimulated luminescence (OSL) ages from Garrett Hill on outwash limit the arrival of the BIIS on the Norfolk coast to 22.8–21.5 ka. Multiple till sheets and chains of moraines on the seafloor north of Norfolk mark dynamic oscillation of the North Sea Lobe margin as it retreated northwards. This pattern of behaviour is broadly synchronous with the terrestrial record of deposition of subglacial, glaciofluvial and glaciolacustrine sediments along the Yorkshire coast which relate to post Dimlington Stadial ice marginal oscillations after 21.5 ka.\ud \ud With respect to forcing mechanisms it is likely that during the early phases of the last glacial maximum (∼30-23ka) the interaction between the southern margin of the BIIS and the Dogger Lake was critical in influencing flow instability and rapid ice advance and retreat. However, during the latter part of the last glacial maximum (22–21 ka) late-phase ice advance in the southern North Sea became restricted to the western side of the Dogger Bank which was a substantial topographic feature by this time. This topographic confinement, in addition to decoupling of the BIIS and the Fennoscandian Ice Sheet (FIS) further north, enabled ice to reach the north Norfolk coast, overprinting the seabed with late-phase tills of the Bolders Bank Fm.

Published
2018

26. Pattern, style and timing of British–Irish Ice Sheet retreat: Shetland and northern North Sea sector

Author

Bradwell, Tom, primary, Small, David, additional, Fabel, Derek, additional, Clark, Chris D., additional, Chiverrell, Richard C., additional, Saher, Margot H., additional, Dove, Dayton, additional, Callard, S. Louise, additional, Burke, Matthew J., additional, Moreton, Steven G., additional, Medialdea, Alicia, additional, Bateman, Mark D., additional, Roberts, David H., additional, Golledge, Nicholas R., additional, Finlayson, Andrew, additional, Morgan, Sally, additional, and Cofaigh, Colm Ó, additional

Published
2019
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27. Ice-stream demise dynamically conditioned by trough shape and bed strength

Author

Bradwell, Tom, primary, Small, David, additional, Fabel, Derek, additional, Smedley, Rachel K., additional, Clark, Chris D., additional, Saher, Margot H., additional, Callard, S. Louise, additional, Chiverrell, Richard C., additional, Dove, Dayton, additional, Moreton, Steven G., additional, Roberts, David H., additional, Duller, Geoff A. T., additional, and Ó Cofaigh, Colm, additional

Published
2019
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28. The mixed‐bed glacial landform imprint of the North Sea Lobe in the western North Sea

Author

Roberts, David H., primary, Grimoldi, Elena, additional, Callard, Louise, additional, Evans, David J.A., additional, Clark, Chris D., additional, Stewart, Heather A., additional, Dove, Dayton, additional, Saher, Margot, additional, Ó Cofaigh, Colm, additional, Chiverrell, Richard C., additional, Bateman, Mark D., additional, Moreton, Steven G., additional, Bradwell, Tom, additional, Fabel, Derek, additional, and Medialdea, Alicia, additional

Published
2019
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30. A stratigraphic investigation of the Celtic Sea megaridges based on seismic and core data from the Irish-UK sectors

Author

Lockhart, Edward A., primary, Scourse, James D., additional, Praeg, Daniel, additional, Van Landeghem, Katrien J.J., additional, Mellett, Claire, additional, Saher, Margot, additional, Callard, Louise, additional, Chiverrell, Richard C., additional, Benetti, Sara, additional, Cofaigh, Colm Ó., additional, and Clark, Chris D., additional

Published
2018
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33. Testate Amoebae as Sea-level Indicators in Northwestern Norway: Developments in Sample Preparation and Analysis.

Author

BARNETT, Robert L., CHARMAN, Dan J., GEHRELS, W. Roland, SAHER, Margot H., and MARSHALL, William A.

Subjects
AMOEBA, BIOINDICATORS, SEA level, SALT marsh ecology, MICROORGANISMS -- Environmental aspects, ALKALIES
Abstract

Proxy based sea-level reconstructions are an important tool for defining past patterns of sea-level change and salt-marsh testate amoebae are a newly emerging proxy with high potential as sea-level indicators. This study develops existing analytical techniques concerned with the preparation and counting of testate amoebae for sea-level studies and demonstrates the predictive power of this group of micro-organisms. Two salt marshes in northwestern Norway were sampled for testate amoebae and multiple sub-samples were prepared using different procedures and count totals. Analytical efficiency can be improved upon by using a mild alkali, chemical disaggregant (5% KOH) to break up fibrous, salt-marsh peat and concentrate tests prior to counting. A count total of 100 individuals, rather than 150, can be used to make time gains with little or no loss of taxon information. The Norwegian salt-marsh testate amoebae showed strong zonation relative to tidal elevation. Key indicator taxa from the high marsh included Centropyxis cassis type, Cyclopyxis arcelloides type and Euglypha spp. Those from the low marsh included Difflugia pristis type and a distinctive morphotype of Centropyxis platystoma type. Combined, the two surface data sets from Norway were capable of predicting marsh surface elevations to within ± 0.09 m. [ABSTRACT FROM AUTHOR]

Published
2013
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34. Benthic foraminifera assemblages in the Central Barents Sea: an evaluation of the effect of combining live and total fauna studies in tracking environmental change.

Author

Saher, Margot, Klitgaard Kristensen, Dorthe, Hald, Morten, Korsun, Sergei, and Jørgensen, Lis Lindal

Subjects
*RHIZOPODA, *FORAMINIFERA, *BENTHIC animals, *SEDIMENTS
Abstract

We present living (stained) benthic foraminifera assemblage data in nine surface sediment samples from the central Barents Sea collected in 2005 and 2006. The abundances of 20 selected species are compared to those from previously published total fauna assemblages of nearby samples. Between 1 and 3 total fauna samples from various years (between 1971 and 1992) are compared with modern (2005 and 2006) samples. The main purpose of the paper is to evaluate the applicability of this comparison. We conclude that, with proper caution, comparing live and total fauna can yield valuable results. Eliminating fragile species, and clustering species according to environmental preferences strengthens the results. A second purpose of the paper is to assess benthic foraminiferal assemblage change in the basin. The data show that foraminiferal assemblage changes vary strongly through out the basin, with maximum change in the extreme north and south of the study area. Division of the species into three major faunal groups related to specific environmental conditions shows that the abundance of cold water species decreases in the eastern part of the study area, while the abundance of warm water species increases in most of the western area. A reverse trend is seen in the most central locality. [ABSTRACT FROM AUTHOR]

Published
2009

37. Pattern, style and timing of British-Irish Ice Sheet retreat: Shetland and northern North Sea sector

Author

Bradwell, Tom, Small, David, Fabel, Derek, Clark, Chris D., Chiverrell, Richard C., Saher, Margot H., Dove, Dayton, Callard, S. Louise, Burke, Matthew J., Moreton, Steven G., Medialdea, Alicia, Bateman, Mark D., Roberts, David H., Golledge, Nicholas R., Finlayson, Andrew, Morgan, Sally, Cofaigh, Colm O., Bradwell, Tom, Small, David, Fabel, Derek, Clark, Chris D., Chiverrell, Richard C., Saher, Margot H., Dove, Dayton, Callard, S. Louise, Burke, Matthew J., Moreton, Steven G., Medialdea, Alicia, Bateman, Mark D., Roberts, David H., Golledge, Nicholas R., Finlayson, Andrew, Morgan, Sally, and Cofaigh, Colm O.

Abstract

The offshore sector around Shetland remains one of the least well-studied parts of the former British-Irish Ice Sheet with several long-standing scientific issues unresolved. These key issues include (i) the dominance of a locally sourced 'Shetland ice cap' vs an invasive Fennoscandian Ice Sheet; (ii) the flow configuration and style of glaciation at the Last Glacial Maximum (i.e. terrestrial vs marine glaciation); (iii) the nature of confluence between the British-Irish and Fennoscandian Ice Sheets; (iv) the cause, style and rate of ice sheet separation; and (v) the wider implications of ice sheet uncoupling on the tempo of subsequent deglaciation. As part of the Britice-Chrono project, we present new geological (seabed cores), geomorphological, marine geophysical and geochronological data from the northernmost sector of the last British-Irish Ice Sheet (north of 59.5 degrees N) to address these questions. The study area covers ca. 95 000 km(2), an area approximately the size of Ireland, and includes the islands of Shetland and the surrounding continental shelf, some of the continental slope, and the western margin of the Norwegian Channel. We collect and analyse data from onshore in Shetland and along key transects offshore, to establish the most coherent picture, so far, of former ice-sheet deglaciation in this important sector. Alongside new seabed mapping and Quaternary sediment analysis, we use a multi-proxy suite of new isotopic age assessments, including 32 cosmogenic-nuclide exposure ages from glacially transported boulders and 35 radiocarbon dates from deglacial marine sediments, to develop a synoptic sector-wide reconstruction combining strong onshore and offshore geological evidence with Bayesian chronosequence modelling. The results show widespread and significant spatial fluctuations in size, shape and flow configuration of an ice sheet/ice cap centred on, or to the east of, the Orkney-Shetland Platform, between similar to 30 and similar to 15 ka BP. A

38. Pattern, style and timing of British-Irish Ice Sheet retreat: Shetland and northern North Sea sector

Author

Bradwell, Tom, Small, David, Fabel, Derek, Clark, Chris D., Chiverrell, Richard C., Saher, Margot H., Dove, Dayton, Callard, S. Louise, Burke, Matthew J., Moreton, Steven G., Medialdea, Alicia, Bateman, Mark D., Roberts, David H., Golledge, Nicholas R., Finlayson, Andrew, Morgan, Sally, Cofaigh, Colm O., Bradwell, Tom, Small, David, Fabel, Derek, Clark, Chris D., Chiverrell, Richard C., Saher, Margot H., Dove, Dayton, Callard, S. Louise, Burke, Matthew J., Moreton, Steven G., Medialdea, Alicia, Bateman, Mark D., Roberts, David H., Golledge, Nicholas R., Finlayson, Andrew, Morgan, Sally, and Cofaigh, Colm O.

Abstract

The offshore sector around Shetland remains one of the least well-studied parts of the former British-Irish Ice Sheet with several long-standing scientific issues unresolved. These key issues include (i) the dominance of a locally sourced 'Shetland ice cap' vs an invasive Fennoscandian Ice Sheet; (ii) the flow configuration and style of glaciation at the Last Glacial Maximum (i.e. terrestrial vs marine glaciation); (iii) the nature of confluence between the British-Irish and Fennoscandian Ice Sheets; (iv) the cause, style and rate of ice sheet separation; and (v) the wider implications of ice sheet uncoupling on the tempo of subsequent deglaciation. As part of the Britice-Chrono project, we present new geological (seabed cores), geomorphological, marine geophysical and geochronological data from the northernmost sector of the last British-Irish Ice Sheet (north of 59.5 degrees N) to address these questions. The study area covers ca. 95 000 km(2), an area approximately the size of Ireland, and includes the islands of Shetland and the surrounding continental shelf, some of the continental slope, and the western margin of the Norwegian Channel. We collect and analyse data from onshore in Shetland and along key transects offshore, to establish the most coherent picture, so far, of former ice-sheet deglaciation in this important sector. Alongside new seabed mapping and Quaternary sediment analysis, we use a multi-proxy suite of new isotopic age assessments, including 32 cosmogenic-nuclide exposure ages from glacially transported boulders and 35 radiocarbon dates from deglacial marine sediments, to develop a synoptic sector-wide reconstruction combining strong onshore and offshore geological evidence with Bayesian chronosequence modelling. The results show widespread and significant spatial fluctuations in size, shape and flow configuration of an ice sheet/ice cap centred on, or to the east of, the Orkney-Shetland Platform, between similar to 30 and similar to 15 ka BP. A

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