Ice-marginal thrusting of drift and bedrock: thermal regime, subglacial aquifers, and glacial surges

Mooers, Howard D.

doi:10.1139/e90-088

Cited by 96 publications

(36 citation statements)

References 20 publications

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“…There are many cited examples where basal meltwater is important in explaining subglacial morphological features with respect to glacier beds of unlithified sediments, such as the deformable bed (Boulton and Jones, 1979), channelized subglacial meltwater transport (Shoemaker, 1986;Alley, 1989), drumlin formation (Boulton, 1987) and glaciotectonic features (van der Wateren, 1992;Mooers, 1990). Others have pointed out the eroding power of subglacial meltwater and its relation to the formation of tunnel valleys (Nye, 1976;Wright, 1973;Boulton and Hindmarsh, 1987) and, to a certain extent, to the origin of glacial basins (van der Wateren, 1992).…”

Section: Modelling Subglacial Hydrologymentioning

confidence: 99%

“…Others have pointed out the eroding power of subglacial meltwater and its relation to the formation of tunnel valleys (Nye, 1976;Wright, 1973;Boulton and Hindmarsh, 1987) and, to a certain extent, to the origin of glacial basins (van der Wateren, 1992). We follow the method applied by Shoemaker (1986), Boulton and Jones (1979) and Mooers (1990) for modelling subglacial hydrology, but we put emphasis on longitudinal ice sheet trends.…”

Section: Modelling Subglacial Hydrologymentioning

confidence: 99%

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Climate-Controlled Glacial Erosion in the Unconsolidated Sediments of Northwestern Europe, Based on a Genetic Model for Tunnel Valley Formation

Dijke¹,

Veldkamp²

1996

Earth Surf. Process. Landforms

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The development of large erosive subglacial forms in unconsolidated sediments is generally attributed to the eroding power of subglacial meltwater flowing under high pressure conditions. Most explanations, however, differ in the source of meltwater and the speed at which it erodes the subglacial bed. Based on the geometry of deep tunnel valleys and glacial basins in northwestern Europe, a reconstruction of subglacial hydrological conditions during the development of subglacial depressions is made. It is demonstrated that the flow of subglacial meltwater in subglacial channels under high glaciostatic pressures is only capable of eroding large volumes of sediment as long as there is imminent glaciohydrological instability. For the thick aquifers in northwestern Europe, this instability is achieved when large quantities of supraglacial meltwater are available. Furthermore, a theoretical definition is given for maximum depression depth to be reached by subglacial erosion. It is shown that this maximum depth is strongly related to average air temperatures during deglaciation and that glacier bed lowering is to be expected during any final phase of glaciations. The theoretical framework presented enables a tentative comparison between large-scale glacial morphology of different glaciations in northwestern Europe.

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Section: Modelling Subglacial Hydrologymentioning

confidence: 99%

Section: Modelling Subglacial Hydrologymentioning

confidence: 99%

Climate-Controlled Glacial Erosion in the Unconsolidated Sediments of Northwestern Europe, Based on a Genetic Model for Tunnel Valley Formation

Dijke¹,

Veldkamp²

1996

Earth Surf. Process. Landforms

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“…However, as ice persisted at Worth Point, permafrost would have warmed from the bottom-up by geothermal heating (Dyke,1993), favouring the addition of water as well as more ductile deformation (cf. Mooers, 1990;Waller et al, 2012). Therefore, the variable physical properties of the permafrozen sediment at Worth Point, and their consequent response to changeable glacial stress regimes, would have evolved over the course of multiple phases of glaciotectonism.…”

Section: Deformation Styles and Structuresmentioning

confidence: 99%

Glaciotectonic deformation and reinterpretation of the Worth Point stratigraphic sequence: Banks Island, NT, Canada

Vaughan

England

Evans

2014

Quaternary Science Reviews

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. (2014) 'Glaciotectonic deformation and reinterpretation of the Worth Point stratigraphic sequence : Banks Island, NT, Canada.', Quaternary science reviews., 91 . pp. 124-145.Further information on publisher's website:http://dx.doi.org/10.1016/j.quascirev. 2013.11.005 Publisher's copyright statement: NOTICE: this is the author's version of a work that was accepted for publication in Quaternary Science Reviews. Changes resulting from the publishing process, such as peer review, editing, corrections, structural formatting, and other quality control mechanisms may not be reected in this document. Changes may have been made to this work since it was submitted for publication. A denitive version was subsequently published in Quaternary Science Reviews, 91, 1 May 2014, 10.1016/j.quascirev.2013 Additional information: Use policyThe full-text may be used and/or reproduced, and given to third parties in any format or medium, without prior permission or charge, for personal research or study, educational, or not-for-prot purposes provided that:• a full bibliographic reference is made to the original source • a link is made to the metadata record in DRO • the full-text is not changed in any way The full-text must not be sold in any format or medium without the formal permission of the copyright holders.Please consult the full DRO policy for further details. Hill-hole pairs, comprising an ice-pushed hill and associated source depression, cluster in a belt along the west coast of Banks Island, NT. Ongoing coastal erosion at Worth Point, southwest Banks Island, has exposed a section (6 km long and w30 m high) through an ice-pushed hill that was transported w 2 km from a corresponding source depression to the southeast. The exposed stratigraphic sequence is polydeformed and comprises folded and faulted rafts of Early Cretaceous and Late Tertiary bedrock, a prominent organic raft, Quaternary glacial sediments, and buried glacial ice. Three distinct structural domains can be identified within the stratigraphic sequence that represent proximal to distal deformation in an ice-marginal setting. Complex thrust sequences, interfering foldsets, brecciated bedrock and widespread shear structures superimposed on this ice-marginally deformed sequence record subsequent deformation in a subglacial shear zone. Analysis of crosscutting relationships within the stratigraphic sequence combined with OSL dating indicate that the Worth Point hill-hole pair was deformed during two separate glaciotectonic events. Firstly, ice sheet advance constructed the hill-hole pair and glaciotectonized the strata ice-marginally, producing a proximal to distal deformation sequence. A glacioisostatically forced marine transgression resulted in extensive reworking of the strata and the deposition of a glaciomarine diamict. A readvance during this initial stage redeformed the strata in a subglacial shear zone, overprinting complex deformation structures and depositing a glaciotectonite w20 m thick. Outwash channels that incise the subglacially deformed strata...

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“…pressures involve restricting subglacial drainage through the freezing of the glacial sole to its substrate in advance of wetbased ice flow (Moran era/., 1980;Mooers, 1990) or freezing of the glacier sole to its bed due to ice accumulation and flow dynamics (Eyles, 1983a, p. 20-23). The former conditions would be expected during glacial onset as the relatively thin and easily chilled margins of glacial ice advanced over permafrost terrain (Eyles, 1983a, p. 21).…”

Section: Moraine De Cirque Dans Glenlyon Range Les Crêtes D'arête Etmentioning

confidence: 99%

The Last Cordilleran Ice Sheet in Southern Yukon Territory

Jackson¹,

Ward²,

Duk-Rodkin³

et al. 2007

gpq

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The Cordilleran Ice Sheet in Yukon radiated from ice-divides in the Selwyn, PeIIy1 Cassiar, and eastern Coast Mountains and was contiguous with a piedmond glacier complex from the St. Elias Mountains. Expansion of glaciers in divide areas could have been underway by 29 ka BP but these did not merge to form the ice sheet until after 24 ka BP. The firn line fell to approximately 1500 m at the climax of McConnell Glaciation. Flow within the ice sheet was more analogous to a complex of merged valley glaciers than to that of extant ice sheets: topographic relief was typically equal to or exceeded ice thickness, and strongly influenced ice flow. Surface gradients on the ice sheet were fractions of a degree. Steeper ice-surface gradients occurred locally along the digitate ice margin. Retreat from the terminal moraine was initially gradual as indicated by recessional moraines within a few tens of kilometres of the terminal moraine. Small magnitude readvances occurred locally. The ice sheet eventually disappeared through regional stagnation and downwasting in response to a rise in the firn line to above the surface of the ice sheet. Regional déglaciation was complete prior to approximately 10 ka BP.L'Inlandsis de la Cordillère a progressé dans le Yukon à partir des lignes de partage des glaces des monts Selwyn, PeIIy et Cassiar et de l'est de la chaîne Côtière; il était contigu à un glacier de piémont complexe en provenance des monts St. Elias. Les glaciers ont pu se développer dans les régions de partage des glaces à partir de 29 ka BP, mais ils ne se sont fusionnés pour former un inlandsis qu'à partir de 24 ka BP. À l'optimum de la Glaciation de McConnell, la ligne de névé s'est abaissée à environ 1500 m. L'écoulement à l'intérieur de l'inlandsis ressemblait davantage à celui d'un complexe de glaciers de vallées coalescents qu'à celui des inlandsis actuels: le relief rejoignait l'épaisseur de glace ou la dépassait et influençait grandement l'écoulement glaciaire. Sur l'inlandsis, les gradients du profil topographique se mesuraient en fractions de degrés, mais le long de la marge digitée, les gradients étaient par endroits plus prononcés. Le retrait à partir de la moraine frontale a au départ été graduel comme l'indiquent les moraines de retrait à quelques dizaines de kilomètres de la moraine frontale. Il y eut localement quelques récurrences mineures. L'inlandsis disparut avec le temps par stagnation à une échelle régionale et fonte en réponse à une hausse de la ligne de névé au-dessus de la surface de l'inlandsis. À l'échelle régionale, la déglaciation était terminée avant 10kaBP environ.Die Kordilleren-Eisdecke in Yukon breitete sich strahlenfôrmig von den Eisscheiden der Seywyn-, Pelley- und Cassiar-Berge und den ôstlichen Kùstenbergen aus und grenzte an einen Vorlandgletscher von den St. Elias-Bergen. Die Ausdehnung der Gletscher in den Eisscheiden-Gebieten kônnte schon um 29 ka v.u.Z. eingesetzt haben; doch sind sie erst nach 24 ka v.u.Z. zu der Eisdecke verschmolzen. Die Firn-Linie sank auf etwa 1500m wâhrend des...

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Ice-marginal thrusting of drift and bedrock: thermal regime, subglacial aquifers, and glacial surges

Cited by 96 publications

References 20 publications

Climate-Controlled Glacial Erosion in the Unconsolidated Sediments of Northwestern Europe, Based on a Genetic Model for Tunnel Valley Formation

Climate-Controlled Glacial Erosion in the Unconsolidated Sediments of Northwestern Europe, Based on a Genetic Model for Tunnel Valley Formation

Glaciotectonic deformation and reinterpretation of the Worth Point stratigraphic sequence: Banks Island, NT, Canada

The Last Cordilleran Ice Sheet in Southern Yukon Territory

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