Borehole imagery of meteoric and marine ice layers in the Amery Ice Shelf, East Antarctica

Craven, Mike; Carsey, F.; Behar, A.; Matthews, J. W.; Brand, Russell; Elcheikh, Alan; Hall, Seane; Treverrow, Adam

doi:10.3189/172756505781829511

Cited by 36 publications

(83 citation statements)

References 37 publications

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“…Platelet ice, a tangible example of this connection, is formed from sea water in the subice shelf environment, and thus blurs the distinction between the regimes. Observations beneath the Amery Ice Shelf [Craven et al, 2005[Craven et al, , 2009 show that marine ice layers are likely to have similar fine-scale structure to the subice platelet matrix observed in considerable detail beneath the sea ice of McMurdo Sound. That being the case, the boundary layer interactions beneath them would be similarly complex.…”

Section: Discussionmentioning

confidence: 92%

Evolution of a supercooled Ice Shelf Water plume with an actively growing subice platelet matrix

et al. 2014

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We use new observations in Western McMurdo Sound, combined with longitudinal hydrographic transects of the sound, to identify a northward-flowing Ice Shelf Water (ISW) plume exiting the cavity of the McMurdo-Ross Ice Shelf. We estimate the plume's net northward transport at 0.4 6 0.1 Sv, carving out a corridor approximately 35 km wide aligned with the Victoria Land Coast. Basal topography of the McMurdo Ice Shelf is such that the plume is delivered to the surface without mixing with overlying warmer water, and is therefore able to remain below the surface freezing temperature at the point of observation beneath first-year ice. Thus, the upper ocean was supercooled, by up to 50 mK at the surface, due to pressure relief from recent rapid ascent of the steep basal slope. The 70 m thick supercooled layer supports the growth and maintenance of a thick, semirigid, and porous matrix of platelet ice, which is trapped by buoyancy at the ice-ocean interface. Continued growth of individual platelets in supercooled water creates significant brine rejection at the top of the water column which resulted in convection over the upper 200 m thick, homogeneous layer. By examining the diffusive nature of the intermediate water between layers of ISW and High Salinity Shelf Water, we conclude that the ISW plume must have originated beneath the Ross Ice Shelf and demonstrate that it is likely to expand eastward across McMurdo Sound with the progression of winter.

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Section: Discussionmentioning

confidence: 92%

Evolution of a supercooled Ice Shelf Water plume with an actively growing subice platelet matrix

et al. 2014

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“…Over the longer term, the highly heterogeneous structure of the ice shelf, and the role revealed here that marine ice could play as part of the mélange in keeping its mechanical integrity and shaping its flow regime also exposes a possible vulnerability. Both the rate of formation of frazil crystals [ Jenkins and Bombosch , 1995; Tison et al , 2001; Khazendar and Jenkins , 2003], and the structural integrity of marine ice layers that result from their accretion, are highly sensitive to the properties of ocean water [ Craven et al , 2005]. In particular, ice shelf basal melting rates are very sensitive to small changes in temperature.…”

Section: Discussionmentioning

confidence: 99%

“…Several Antarctic ice shelves have been shown to be composed of marine ice, several tens of meters in thickness, at many locations [e.g., Morgan , 1972; Oerter et al , 1994; Fricker et al , 2001]. Distinct from meteoric or sea ice, marine ice forms when frazil ice crystals accumulate at the base of an ice shelf as part of the thermohaline circulation in the underlying cavity [ Jenkins and Bombosch , 1995] and subsequently consolidate into layers, the lower of which can be highly porous [ Engelhardt and Determann , 1987; Craven et al , 2005]. Fracture, itself a critical aspect of ice shelf stability, is often affected by marine ice, which can fill rifts and bottom crevasses [ Khazendar et al , 2001; Khazendar and Jenkins , 2003].…”

Section: Introductionmentioning

confidence: 99%

Roles of marine ice, rheology, and fracture in the flow and stability of the Brunt/Stancomb‐Wills Ice Shelf

2009

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[1] Marine ice, sometimes as part of an ice mélange, significantly affects ice shelf flow and ice fracture. The highly heterogeneous structure of the Brunt/Stancomb-Wills Ice Shelf (BSW) system in the east Weddell Sea offers a rare setting for uncovering the difference in rheology between meteoric and marine ice. Here, we use data assimilation to infer the rheology of the Brunt/Stancomb-Wills Ice Shelf by an inverse control method that combines interferometric synthetic aperture radar measurements with numerical modeling. We then apply the inferred rheology to support the hypothesis attributing the observed 1970s ice shelf flow acceleration to a change in the stiffness of the ice mélange area connecting Brunt proper with Stancomb-Wills and to examine the consequences of frontal rift propagation. We conclude that while the Brunt/Stancomb-Wills system is currently not susceptible to extreme fragmentation similar to that of the Larsen B Ice Shelf in 2002, our inverse and forward modeling results emphasize its vulnerability to destabilization by relatively rapid changes in the ice mélange properties, resulting from the interaction of its marine ice component with ocean water, or by the further propagation of a frontal rift.Citation: Khazendar, A., E. Rignot, and E. Larour (2009), Roles of marine ice, rheology, and fracture in the flow and stability of the Brunt/Stancomb-Wills Ice Shelf,

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“…1) under ice shelves is difficult to observe directly (Craven et al, 2005), but similar effects are readily observed beneath nearby sea ice where it is called platelet ice (e.g. Robinson et al, 2014;Hughes et al, 2014;Hoppmann et al, 2015;Langhorne et al, 2015).…”

Section: Introductionmentioning

confidence: 99%

“…In this way, fresh glacial ice near the grounding line can be transformed to marine ice (Langhorne, 2008). Evidence from icebergs (Kipfstuhl et al, 1992), borehole (Craven et al, 2005) and radar studies (Engelhardt and Determann, 1987;Robin et al, 1983;Holland et al, 2009) indicate that marine ice can reach appreciable thicknesses, and that the ice pump is active under shelves where the water entering the cavity is near freezing.…”

Section: Introductionmentioning

confidence: 99%

Turbulent heat transfer as a control of platelet ice growth in supercooled under-ice ocean boundary layers

et al. 2016

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Abstract. Late winter measurements of turbulent quantities in tidally modulated flow under land-fast sea ice near the Erebus Glacier Tongue, McMurdo Sound, Antarctica, identified processes that influence growth at the interface of an ice surface in contact with supercooled seawater. The data show that turbulent heat exchange at the ocean-ice boundary is characterized by the product of friction velocity and (negative) water temperature departure from freezing, analogous to similar results for moderate melting rates in seawater above freezing. Platelet ice growth appears to increase the hydraulic roughness (drag) of fast ice compared with undeformed fast ice without platelets. Platelet growth in supercooled water under thick ice appears to be rate-limited by turbulent heat transfer and that this is a significant factor to be considered in mass transfer at the underside of ice shelves and sea ice in the vicinity of ice shelves.

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Borehole imagery of meteoric and marine ice layers in the Amery Ice Shelf, East Antarctica

Cited by 36 publications

References 37 publications

Evolution of a supercooled Ice Shelf Water plume with an actively growing subice platelet matrix

Evolution of a supercooled Ice Shelf Water plume with an actively growing subice platelet matrix

Roles of marine ice, rheology, and fracture in the flow and stability of the Brunt/Stancomb‐Wills Ice Shelf

Turbulent heat transfer as a control of platelet ice growth in supercooled under-ice ocean boundary layers

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