Ice sheet grounding zone stabilization due to till compaction

Christianson, Knut; Parizek, B. R.; Alley, Richard B.; Horgan, Huw; Jacobel, R. W.; Anandakrishnan, S.; Keisling, B. A.; Craig, B.; Muto, Atsuhiro

doi:10.1002/2013gl057447

Cited by 47 publications

(61 citation statements)

References 44 publications

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“…The KIS trunk estuary shows some similarities to the WIS trunk estuary reported by Horgan et al (2013) and Christianson et al (2013), i.e., similarities in the shapes of the estuaries, potential saddles dividing the estuaries from upstream potential lows and upstream subglacial lakes which probably supply subglacial water into the estuaries. However, the KIS trunk estuary is located on the upstream side of the current grounding line and has higher hydraulic potentials (300-500 kPa), indicating that it is entirely grounded at present; whereas the estuary downstream of the WIS, with almost 0 kPa potential, is probably exchanging water and sediment across the grounding zone through viscoelastic flexure induced by tidal forcing.…”

Section: Discussionsupporting

confidence: 58%

Active subglacial lakes and channelized water flow beneath the Kamb Ice Stream

et al. 2016

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Abstract. We identify two previously unknown subglacial lakes beneath the stagnated trunk of the Kamb Ice Stream (KIS). Rapid fill-drain hydrologic events over several months are inferred from surface height changes measured by CryoSat-2 altimetry and indicate that the lakes are probably connected by a subglacial drainage network, whose structure is inferred from the regional hydraulic potential and probably links the lakes. The sequential fill-drain behavior of the subglacial lakes and concurrent rapid thinning in a channel-like topographic feature near the grounding line implies that the subglacial water repeatedly flows from the region above the trunk to the KIS grounding line and out beneath the Ross Ice Shelf. Ice shelf elevation near the hypothesized outlet is observed to decrease slowly during the study period. Our finding supports a previously published conceptual model of the KIS shutdown stemming from a transition from distributed flow to well-drained channelized flow of subglacial water. However, a water-piracy hypothesis in which the KIS subglacial water system is being starved by drainage in adjacent ice streams is also supported by the fact that the degree of KIS trunk subglacial lake activity is relatively weaker than those of the upstream lakes.

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Section: Discussionsupporting

confidence: 58%

Active subglacial lakes and channelized water flow beneath the Kamb Ice Stream

et al. 2016

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“…Low bed slopes in these regions are qualitatively consistent with observations of lower bed roughness there, particularly for Petermann Glacier [ Rippin , ]. The lack of bed‐conforming radiostratigraphy in these regions suggests strong and long‐term organization of ice flow that is consistent with pattern of surface velocity [ Joughin et al ., ] and may be further modulated by spatiotemporal variation in basal friction [e.g., Hindmarsh et al ., ; Christianson et al ., , ]. This pattern is distinct from observations of some Antarctic glaciers that contain disrupted radiostratigraphy, which has been interpreted as evidence of fast ice flow in the past [e.g., Catania et al ., ; Rippin et al ., ].…”

Section: Resultsmentioning

confidence: 68%

“…Having traced the radiostratigraphy using the methods described above, we then seek to date these observed reflections. While inferences regarding ice sheet dynamics from reflection morphology alone are valuable [e.g., Conway et al ., ; Catania et al ., ; Hindmarsh et al ., ; Rippin et al ., ; Catania and Neumann , ; Campbell et al ., ; Christianson et al ., ; Sime et al ., ], the value of traced reflections can increase substantially if they are also dated [e.g., Whillans , ; Fahnestock et al ., ; Baldwin et al ., ; Dahl‐Jensen et al ., ; Buchardt , ; Medley et al ., ]. Hence, we seek to date as many traced reflections as possible, even those that do not intersect an ice core and are not continuous.…”

Section: Methodsmentioning

confidence: 99%

Radiostratigraphy and age structure of the Greenland Ice Sheet

et al. 2015

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Several decades of ice-penetrating radar surveys of the Greenland and Antarctic ice sheets have observed numerous widespread internal reflections. Analysis of this radiostratigraphy has produced valuable insights into ice sheet dynamics and motivates additional mapping of these reflections. Here we present a comprehensive deep radiostratigraphy of the Greenland Ice Sheet from airborne deep ice-penetrating radar data collected over Greenland by The University of Kansas between 1993 and 2013. To map this radiostratigraphy efficiently, we developed new techniques for predicting reflection slope from the phase recorded by coherent radars. When integrated along track, these slope fields predict the radiostratigraphy and simplify semiautomatic reflection tracing. Core-intersecting reflections were dated using synchronized depth-age relationships for six deep ice cores. Additional reflections were dated by matching reflections between transects and by extending reflection-inferred depth-age relationships using the local effective vertical strain rate. The oldest reflections, dating to the Eemian period, are found mostly in the northern part of the ice sheet. Within the onset regions of several fast-flowing outlet glaciers and ice streams, reflections typically do not conform to the bed topography. Disrupted radiostratigraphy is also observed in a region north of the Northeast Greenland Ice Stream that is not presently flowing rapidly. Dated reflections are used to generate a gridded age volume for most of the ice sheet and also to determine the depths of key climate transitions that were not observed directly. This radiostratigraphy provides a new constraint on the dynamics and history of the Greenland Ice Sheet.Key PointsPhase information predicts reflection slope and simplifies reflection tracingReflections can be dated away from ice cores using a simple ice flow modelRadiostratigraphy is often disrupted near the onset of fast ice flow

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“…Higher order (HO) models include additional stresses to allow stress transmission across floating and grounded ice, while Full-Stokes (FS) models resolve all stresses. Adapted from Pattyn et al (2006) of the nature of the underlying bed (Christianson et al, 2013) and the evolution in properties of basal conditions (Gillet-Chaulet et al, 2016). Such processes and understanding are starting to be implemented in regional ISMs and should be more systematically included in future simulations.…”

Section: An Improved Generation Of Modelsmentioning

confidence: 99%