Englacial Warming Indicates Deep Crevassing in Bowdoin Glacier, Greenland

Seguinot, Julien; Funk, Martin; Bauder, Andreas; Wyder, Thomas; Senn, Cornelius; Sugiyama, Shin

doi:10.3389/feart.2020.00065

Cited by 15 publications

(23 citation statements)

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“…The energy input and sink required to sustain the anomaly can be used to estimate the deformation rate. Strain heating, Q s , is expressed as

, where τ is the deviatoric stress tensor and

is the strain rate tensor ( 10 , 16 ). Stress and strain are related via

( 44 , 45 ), where τ e is the effective stress and

, and A is the creep parameter, which we take as 7.7 × 10 −25 s −1 Pa −3 following aggregate values in Cuffey and Paterson [( 16 ), table 3.3] with the range 6.7 × 10 −25 to 8.7 × 10 −25 s −1 Pa −3 , used to test parameter sensitivity and the flow exponent n ≈ 3.…”

Section: Methodsmentioning

confidence: 99%

“…The energy input and sink required to sustain the anomaly can be used to estimate the deformation rate. Strain heating, Q s , is expressed as Q s = tr( ̇ ) , where  is the deviatoric stress tensor and ̇ is the strain rate tensor (10,16). Stress and strain are related via ̇ = A  e n−1  (44,45), where  e is the effective stress and τ e 2 = 1 _ 2 tr(  2 ) , and A is the creep parameter, which we take as 7.…”

Section: Anomaly-208 Heat Transfer and Deformationmentioning

confidence: 99%

“…Such glaciers drain most of the ice sheet ( 2 , 8 ), yet they are rarely the subject of borehole investigations due to logistical challenges including pervasive crevassing and high strain rates that damage installed equipment [e.g. ( 7 , 9 , 10 )]. As a consequence, GrIS models often rely on physical constraints from theoretical considerations or from studies conducted on smaller and more accessible glaciers elsewhere, which may not be representative of larger or faster ice masses [e.g.…”

Section: Introductionmentioning

confidence: 99%

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Thermodynamics of a fast-moving Greenlandic outlet glacier revealed by fiber-optic distributed temperature sensing

et al. 2021

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Measurements of ice temperature provide crucial constraints on ice viscosity and the thermodynamic processes occurring within a glacier. However, such measurements are presently limited by a small number of relatively coarse-spatial-resolution borehole records, especially for ice sheets. Here, we advance our understanding of glacier thermodynamics with an exceptionally high-vertical-resolution (~0.65 m), distributed-fiber-optic temperature-sensing profile from a 1043-m borehole drilled to the base of Sermeq Kujalleq (Store Glacier), Greenland. We report substantial but isolated strain heating within interglacial-phase ice at 208 to 242 m depth together with strongly heterogeneous ice deformation in glacial-phase ice below 889 m. We also observe a high-strain interface between glacial- and interglacial-phase ice and a 73-m-thick temperate basal layer, interpreted as locally formed and important for the glacier’s fast motion. These findings demonstrate notable spatial heterogeneity, both vertically and at the catchment scale, in the conditions facilitating the fast motion of marine-terminating glaciers in Greenland.

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“…The energy input and sink required to sustain the anomaly can be used to estimate the deformation rate. Strain heating, Q s , is expressed as

, where τ is the deviatoric stress tensor and

is the strain rate tensor ( 10 , 16 ). Stress and strain are related via

( 44 , 45 ), where τ e is the effective stress and

Section: Methodsmentioning

confidence: 99%

Section: Anomaly-208 Heat Transfer and Deformationmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Thermodynamics of a fast-moving Greenlandic outlet glacier revealed by fiber-optic distributed temperature sensing

et al. 2021

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“…Moulins have been shown to migrate horizontally with depth (Holmund, 1988), which could possibly avoid this objection; however, numerous moulins would be needed to generate the cooling we observe in multiple boreholes. In the ablation zone surrounding Issunguata Sermia, active moulins have a mean density of 0.1 per square kilometer (Smith et al, 2015), and Catania and Neumann (2010) found relict moulins to be spaced ∼ 1 km apart, which suggests that it is unlikely that multiple moulins have thermally altered the instrumented block of ice with a surface area of ∼ 0.125 km 2 .…”

Section: Thermal Decay From Basal Crevassesmentioning

confidence: 99%

The cooling signature of basal crevasses in a hard-bedded region of the Greenland Ice Sheet

et al. 2021

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Abstract. Temperature sensors installed in a grid of nine full-depth boreholes drilled in the southwestern ablation zone of the Greenland Ice Sheet recorded cooling in discrete sections of ice over time within the lowest third of the ice column in most boreholes. Rates of temperature change outpace cooling expected from vertical conduction alone. Additionally, observed temperature profiles deviate significantly from the site-average thermal profile that is shaped by all thermomechanical processes upstream. These deviations imply recent, localized changes to the basal thermal state in the boreholes. Although numerous heat sources exist to add energy and warm ice as it moves from the central divide towards the margin such as strain heat from internal deformation, latent heat from refreezing meltwater, and the conduction of geothermal heat across the ice–bedrock interface, identifying heat sinks proves more difficult. After eliminating possible mechanisms that could cause cooling, we find that the observed cooling is a manifestation of previous warming in near-basal ice. Thermal decay after latent heat is released from freezing water in basal crevasses is the most likely mechanism resulting in the transient evolution of temperature and the vertical thermal structure observed at our site. We argue basal crevasses are a viable englacial heat source in the basal ice of Greenland's ablation zone and may have a controlling influence on the temperature structure of the near-basal ice.

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“…1a). Field campaigns on Bowdoin Glacier were repeated in the summers of 2013-2017 and 2019 in a collaboration between Hokkaido University, ETH Zurich and University of Florence (Podolskiy et al, 2017;Seguinot et al, 2020).…”

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confidence: 99%

Thinning leads to calving-style changes at Bowdoin Glacier, Greenland

Dongen¹,

Jouvet²,

Sugiyama³

et al. 2020

Preprint

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Abstract. Ice mass loss from the Greenland Ice Sheet is the largest single contributor to sea-level rise in the 21st century. The mass loss rate has accelerated in recent decades mainly due to thinning and retreat of its outlet glaciers. The diverse calving mechanisms responsible for tidewater glacier retreat are not fully understood yet. Since a tidewater glacier’s sensitivity to external forcings depends on its calving style, a detailed insight into calving processes is necessary to improve projections of ice sheet mass loss by calving. As tidewater glaciers are mostly thinning, their calving styles are expected to change. Here, we study calving behaviour changes under a thinning regime at Bowdoin Glacier, Northwest Greenland, by combining field and remote sensing data from 2015 to 2019. Previous studies showed that major calving events in 2015 and 2017 were driven by hydro-fracturing and melt-undercutting. New observations from UAV imagery and a GPS network installed at the calving front in 2019 suggest ungrounding and buoyant calving have recently occurred, as they show (1) increasing tidal modulation of vertical motion compared to previous years, (2) absence of a surface crevasse prior to calving, and (3) uplift and horizontal surface compression prior to calving. Furthermore, an inventory of calving events from 2015 to 2019 based on satellite imagery provides additional support for a change towards buoyant calving since it shows an increasing occurrence of calving events outside of the melt season. The observed change of calving style could lead to a possible retreat of the terminus, which has been stable since 2013. We therefore highlight the need for high-resolution monitoring to detect changing calving styles and numerical models that cover the full spectrum of calving mechanisms to improve projections of ice sheet mass loss by calving.

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Englacial Warming Indicates Deep Crevassing in Bowdoin Glacier, Greenland

Cited by 15 publications

References 50 publications

Thermodynamics of a fast-moving Greenlandic outlet glacier revealed by fiber-optic distributed temperature sensing

Thermodynamics of a fast-moving Greenlandic outlet glacier revealed by fiber-optic distributed temperature sensing

The cooling signature of basal crevasses in a hard-bedded region of the Greenland Ice Sheet

Thinning leads to calving-style changes at Bowdoin Glacier, Greenland

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