Ice sheets viewed from the ocean: the contribution of marine science to understanding modern and past ice sheets

Cofaigh, Colm Ó

doi:10.1098/rsta.2012.0398

Cited by 20 publications

(21 citation statements)

References 123 publications

(191 reference statements)

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“…The significant differences in gully incision depth and shelf-indentation observed between some Arctic and Antarctic gullies may therefore reflect differences in the timing of initial glaciation and the number of Subbottom data from some high latitude margins (e.g., Storfjorden TMF, northern Barents Sea; Belgica Fan, Bellingshausen Sea, Antarctica) show that submarine gullies incise glacial debris flow deposits, suggesting that erosion of some gullies likely post-dates the last glacial advance to the shelf edge (Vorren et al, 1989;Laberg et al, 2007;Pedrosa et al, 2011;Ó Cofaigh, 2012). As the most recent episodes of gully erosion (since LGM) may obscure previously developed gullies, it is difficult to rule out gully formation over longer timescales without high resolution three-dimensional seismic datasets from glacial margins.…”

Section: Long-term Versus Short-term Gully Formationmentioning

confidence: 99%

Arctic and Antarctic submarine gullies—A comparison of high latitude continental margins

et al. 2013

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Submarine gullies are common features of high latitude continental slopes and, over the last decade, have been shown to play a key role in continental margin evolution, submarine erosion, downslope sediment transport, slope deposits, and the architecture of petroleum reservoirs. However, the processes that form these gullies, the timescales over which they develop, and the environmental controls influencing their morphology remain poorly constrained. We present the first systematic and comparative analysis between Arctic and Antarctic gullies with the aim of identifying differences in slope character, from which we infer differences in processes operating in these environments.Quantitative analysis of multibeam echosounder data along 2469 km of the continental shelf and upper slope and morphometric signatures of over 1450 gullies show that six geomorphically distinct gully types exist on high latitude continental margins. We identify distinct differences between Arctic and Antarctic gully morphologies. In the Arctic data sets, deep relief (> 30 m gully incision depth at 50 m below the shelf edge) and shelfincising gullies are lacking. These differences have implications for the timescales over which the gullies were formed and for the magnitude of the flows that formed them. We consider two hypotheses for these differences: (1) some Antarctic gullies developed through several glacial cycles; and (2) larger Antarctic gullies were formed since the Last Glacial Maximum as a result of erosive flows (i.e., sediment-laden subglacial meltwater) being more abundant on parts of the Antarctic margin over longer timescales.A second difference is that unique gully signatures are observed on Arctic and on Antarctic margins. Environmental controls, such as the oceanographic regime and geotechnical differences, may lead to particular styles of gully erosion observed on Arctic and Antarctic margins.

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Section: Long-term Versus Short-term Gully Formationmentioning

confidence: 99%

Arctic and Antarctic submarine gullies—A comparison of high latitude continental margins

et al. 2013

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“…It has only been over the last two decades, however, that the principles could be adequately applied in a marine setting, where geophysical data have become sufficiently high resolution. Also, glacigenic features are often better preserved in a submarine setting as they have not been subject to millennia of subaerial erosion, and thus marine observations are critical for reconstructing the extent and flow dynamics of past glaciations (Ó Cofaigh, 2012). …”

Section: Methods 1: Submarine Glacial Geomorphologymentioning

confidence: 99%

Seabed Characterization: Developing Fit for Purpose Methodologies

Dove¹,

Cooper²,

Lark³

et al. 2014

Near Surface Geoscience 2014 - First Applied Shallow Marine Geophysics Conference

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SUMMARYWe briefly describe three methods of seabed characterization which are 'fit for purpose', in that each approach is well suited to distinct objectives e.g. characterizing glacial geomorphology and shallow glacial geology vs. rapid prediction of seabed sediment distribution via geostatistics. The methods vary from manual 'expert' interpretation to increasingly automated and mathematically based models, each with their own attributes and limitations. We would note however that increasing automation and mathematical sophistication does not necessarily equate to improve map outputs, or reduce the time required to produce them. Judgements must be made to select methodologies which are most appropriate to the variables mapped, and according to the extent and presentation scale of final maps.

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“…In turn, this is enabling insights into wider Earth system processes and the coupling of ice-sheet dynamics, ocean processes, climate, the rheology of the upper mantle, glacio-isostatic adjustment and relative sea-level change (Milne et al, 2006;Bradley et al, 2011). Such understanding is not only of academic interest but is of critical importance in informing assessments of the future responses of modern marine-based ice sheets to likely 21st century climate warming, sea-level rise and possible changes in ocean circulation (Clark et al, 2012;Ó Cofaigh, 2012). For example, the British-Irish Ice Sheet may be an analogue for the marine-based West Antarctic Ice Sheet, the future stability of which is a key concern in a warmer world (Vaughan and Arthern, 2007;Lenton et al, 2008), and help to provide empirical evidence to test numerical models of dynamic, fastflowing ice sheets (Boulton and Hagdorn, 2006;Hubbard et al, 2009).…”

Section: The Quaternary Of Scotlandmentioning

confidence: 99%

Progress in marine geoconservation in Scotland’s seas: assessment of key interests and their contribution to Marine Protected Area network planning

Gordon

Brooks²,

Chaniotis

et al. 2016

Proceedings of the Geologists' Association

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Geoconservation in the marine environment has been largely overlooked, despite a wealth of accumulated information on marine geology and geomorphology and clear links between many terrestrial and marine features. As part of the wider characterisation of Scotland's seas, this study developed criteria and a methodology that follow the established principles of the terrestrial, Great Britain-wide geoconservation audit, the Geological Conservation Review, to assess geodiversity key areas on the seabed. Using an expert judgement approach, eight geodiversity feature categories were identified to represent the geological and geomorphological processes that have influenced the evolution and present-day morphology of the Scottish seabed: Quaternary of Scotland; Submarine Mass Movement; Marine Geomorphology of the Scottish Deep-Ocean Seabed; Seabed Fluid and Gas Seep; Cenozoic Structures of the Atlantic Margin; Marine Geomorphology of the Scottish Shelf Seabed; Coastal Geomorphology of Scotland; and Biogenic Structures of the Scottish Seabed. Within these categories, 35 key areas were prioritised for their scientific value. Specific interests range from large-scale landforms (e.g. submarine landslides, sea-mounts and trenches) to fine-scale dynamic features (e.g. sand waves). Although these geodiversity interests provided supporting evidence for the identification and selection of a suite of Nature Conservation Marine Protected Areas (MPAs) containing important marine natural features, they are only partially represented in these MPAs and existing protected areas. Nevertheless, a pragmatic 2 approach is emerging to integrate as far as possible the conservation management of marine geodiversity with that of biodiversity and based on evidence of the sensitivity and vulnerability of geological and geomorphological features on the seabed.

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Ice sheets viewed from the ocean: the contribution of marine science to understanding modern and past ice sheets

Cited by 20 publications

References 123 publications

Arctic and Antarctic submarine gullies—A comparison of high latitude continental margins

Arctic and Antarctic submarine gullies—A comparison of high latitude continental margins

Seabed Characterization: Developing Fit for Purpose Methodologies

Progress in marine geoconservation in Scotland’s seas: assessment of key interests and their contribution to Marine Protected Area network planning

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