Bed conditions of Pine Island Glacier, West Antarctica

Brisbourne, Alex; Smith, Andrew M.; Vaughan, David G.; King, Edward C.; Davies, Damon; Bingham, Robert G.; Smith, Emma C.; Nias, Isabel; Rosier, Sebastian

doi:10.1002/2016jf004033

Cited by 39 publications

(58 citation statements)

References 60 publications

(103 reference statements)

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“…These surveys inferred a thick sedimentary basin extending upstream of the grounding line that would provide an abundant source for sediments deposited as mass flows, MSGL, and GZWs in Zones 2–4. These observations indicate that Jenkins Ridge marks a transition between hard, resistant crystalline bedrock to more erodible, soft sedimentary bed upstream of the present‐day grounding line [ Brisbourne et al , ]. Such transitions have been observed farther seaward on the continental shelf and associated with contrasts in the distribution of sediment and character of geomorphic features [ Lowe and Anderson , ; Wellner et al , , ; Graham et al , ].…”

Section: Discussionmentioning

confidence: 99%

High‐resolution sub‐ice‐shelf seafloor records of twentieth century ungrounding and retreat of Pine Island Glacier, West Antarctica

et al. 2017

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Pine Island Glacier Ice Shelf (PIGIS) has been thinning rapidly over recent decades, resulting in a progressive drawdown of the inland ice and an upstream migration of the grounding line. The resultant ice loss from Pine Island Glacier (PIG) and its neighboring ice streams presently contributes an estimated ∼10% to global sea level rise, motivating efforts to constrain better the rate of future ice retreat. One route toward gaining a better understanding of the processes required to underpin physically based projections is provided by examining assemblages of landforms and sediment exposed over recent decades by the ongoing ungrounding of PIG. Here we present high‐resolution bathymetry and sub‐bottom‐profiler data acquired by autonomous underwater vehicle (AUV) surveys beneath PIGIS in 2009 and 2014, respectively. We identify landforms and sediments associated with grounded ice flow, proglacial and subglacial sediment transport, overprinting of lightly grounded ice‐shelf keels, and stepwise grounding line retreat. The location of a submarine ridge (Jenkins Ridge) coincides with a transition from exposed crystalline bedrock to abundant sediment cover potentially linked to a thick sedimentary basin extending upstream of the modern grounding line. The capability of acquiring high‐resolution data from AUV platforms enables observations of landforms and understanding of processes on a scale that is not possible in standard offshore geophysical surveys.

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Section: Discussionmentioning

confidence: 99%

High‐resolution sub‐ice‐shelf seafloor records of twentieth century ungrounding and retreat of Pine Island Glacier, West Antarctica

et al. 2017

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“…4a) The physical properties of the bed between PIG and RIS also differ. Seismic reflection surveying of several sites along PIG's trunk, including upstream and downstream of our repeat survey sites, has confirmed that the bed immediately below the ice pervasively consists of dilated sediments, which are at least several metres thick Brisbourne et al, 2017). Along seismic profile S1 2007 potentialfield data indicate that a transition from sedimentary to crystalline bedrock lies beneath the cap of deformable sediments (at position 9 km on Fig.…”

Section: Are Ice-stream Beds Dynamic?mentioning

confidence: 99%

“…2a, 3a and 3f, black lines are repeat radar surveys. S1 2007 is a seismic survey presented in Smith et al (2013) and S1 2014 is a section of this profile resurveyed in 2014 (presented in Brisbourne et al, 2017). EHT31 is a single point repeat survey presented in Smith et al (2012).…”

Section: Data Acquisitionmentioning

confidence: 99%

“…Therefore we compare relative bed profiles by applying a static correction to a common bed datum (0 m) for both surveys. The seismic surveys S1 2007 and S1 2014 in the vicinity of R1 were processed and analysed by Smith et al (2013; profile only) and Brisbourne et al (2017;both profiles). Brisbourne et al (2017) primarily report on the calculation of acoustic impedance at the bed from both profiles, which we will consider in our discussion below.…”

Section: Data Processingmentioning

confidence: 99%

“…The seismic surveys S1 2007 and S1 2014 in the vicinity of R1 were processed and analysed by Smith et al (2013; profile only) and Brisbourne et al (2017;both profiles). Brisbourne et al (2017) primarily report on the calculation of acoustic impedance at the bed from both profiles, which we will consider in our discussion below. For this paper, we also investigated the possibility of directly picking the bed for the repeated 5 km section in an analogous manner to the radar picking described above.…”

Section: Data Processingmentioning

confidence: 99%

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How dynamic are ice-stream beds?

et al. 2018

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Abstract. Projections of sea-level rise contributions from West Antarctica's dynamically thinning ice streams contain high uncertainty because some of the key processes involved are extremely challenging to observe. An especially poorly observed parameter is sub-decadal stability of ice-stream beds, which may be important for subglacial traction, till continuity and landform development. Only two previous studies have made repeated geophysical measurements of ice-stream beds at the same locations in different years, but both studies were limited in spatial extent. Here, we present the results from repeat radar measurements of the bed of Pine Island Glacier, West Antarctica, conducted 3-6 years apart, along a cumulative ∼ 60 km of profiles. Analysis of the correlation of bed picks between repeat surveys shows that 90 % of the bed displays no significant change despite the glacier increasing in speed by up to 40 % over the last decade. We attribute the negligible detection of morphological change at the bed of Pine Island Glacier to the ubiquitous presence of a deforming till layer, wherein sediment transport is in steady state, such that sediment is transported along the basal interface without inducing morphological change to the radarsounded basal interface. Given the precision of our measurements, the upper limit of subglacial erosion observed here is 500 mm a −1 , far exceeding erosion rates reported for glacial settings from proglacial sediment yields, but substantially below subglacial erosion rates of 1.0 m a −1 previously reported from repeat geophysical surveys in West Antarctica.

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New Mass‐Conserving Bedrock Topography for Pine Island Glacier Impacts Simulated Decadal Rates of Mass Loss

Nias

Cornford

Payne

2018

Geophysical Research Letters

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High‐resolution ice flow modeling requires bedrock elevation and ice thickness data, consistent with one another and with modeled physics. Previous studies have shown that gridded ice thickness products that rely on standard interpolation techniques (such as Bedmap2) can be inconsistent with the conservation of mass, given observed velocity, surface elevation change, and surface mass balance, for example, near the grounding line of Pine Island Glacier, West Antarctica. Using the BISICLES ice flow model, we compare results of simulations using both Bedmap2 bedrock and thickness data, and a new interpolation method that respects mass conservation. We find that simulations using the new geometry result in higher sea level contribution than Bedmap2 and reveal decadal‐scale trends in the ice stream dynamics. We test the impact of several sliding laws and find that it is at least as important to accurately represent the bedrock and initial ice thickness as the choice of sliding law.

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Bed conditions of Pine Island Glacier, West Antarctica

Cited by 39 publications

References 60 publications

High‐resolution sub‐ice‐shelf seafloor records of twentieth century ungrounding and retreat of Pine Island Glacier, West Antarctica

High‐resolution sub‐ice‐shelf seafloor records of twentieth century ungrounding and retreat of Pine Island Glacier, West Antarctica

How dynamic are ice-stream beds?

New Mass‐Conserving Bedrock Topography for Pine Island Glacier Impacts Simulated Decadal Rates of Mass Loss

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