A balanced water layer concept for subglacial hydrology in large-scale ice sheet models

Goeller, Sebastian; Thoma, Malte; Grosfeld, Klaus; Miller, Heinz

doi:10.5194/tc-7-1095-2013

Cited by 30 publications

(37 citation statements)

References 57 publications

(58 reference statements)

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“…An improved representation of ice dynamics within our model could support a faster grounding-line migration within shorter time spans in conjunction with a faster sea-level rise. To quantify this, future simulations should better resolve ice-stream dynamics, especially basal frictional processes governed by, e.g., lubrication through subglacial water (Goeller et al, 2013). Such an approach could reproduce fast-flowing glaciers with their potential to drain the ice sheet faster.…”

Section: Discussionmentioning

confidence: 99%

Future sea-level rise due to projected ocean warming beneath the Filchner Ronne Ice Shelf: A coupled model study

Thoma

Determann

Grosfeld

et al. 2015

Earth and Planetary Science Letters

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A general ocean circulation model is coupled with a 3D-thermodynamical ice-sheet/shelf model to simulate the response of the Filchner-Ronne Ice Shelf (FRIS, Antarctica) and coastal parts of its catchment basin to a postulated inflow of Warm Deep Water into the ice-shelf cavity on a 1000-yr timescale. Prescribed ocean warming (based on climate projections) enters the ice-shelf cavity in the up to 1500 m deep Filchner Trough and penetrates deep into the sub-ice cavity. Increasing basal melt rates induce geometry changes of the cavity, which in turn have an impact on the ocean circulation and therefore the modelled melt rates. Highest melt rates of about 20 m yr

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Section: Discussionmentioning

confidence: 99%

Future sea-level rise due to projected ocean warming beneath the Filchner Ronne Ice Shelf: A coupled model study

Thoma

Determann

Grosfeld

et al. 2015

Earth and Planetary Science Letters

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“…Compared to existing largescale models (e.g. Le Brocq et al, 2009;Goeller et al, 2013), our model effectively computes the effective pressure. This feature makes it comparable to more physically based models (e.g.…”

Section: Discussionmentioning

confidence: 99%

A double continuum hydrological model for glacier applications

et al. 2014

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Abstract. The flow of glaciers and ice streams is strongly influenced by the presence of water at the interface between ice and bed. In this paper, a hydrological model evaluating the subglacial water pressure is developed with the final aim of estimating the sliding velocities of glaciers. The global model fully couples the subglacial hydrology and the ice dynamics through a water-dependent friction law. The hydrological part of the model follows a double continuum approach which relies on the use of porous layers to compute water heads in inefficient and efficient drainage systems. This method has the advantage of a relatively low computational cost that would allow its application to large ice bodies such as Greenland or Antarctica ice streams. The hydrological model has been implemented in the finite element code Elmer/Ice, which simultaneously computes the ice flow. Herein, we present an application to the Haut Glacier d'Arolla for which we have a large number of observations, making it well suited to the purpose of validating both the hydrology and ice flow model components. The selection of hydrological, under-determined parameters from a wide range of values is guided by comparison of the model results with available glacier observations. Once this selection has been performed, the coupling between subglacial hydrology and ice dynamics is undertaken throughout a melt season. Results indicate that this new modelling approach for subglacial hydrology is able to reproduce the broad temporal and spatial patterns of the observed subglacial hydrological system. Furthermore, the coupling with the ice dynamics shows good agreement with the observed spring speed-up.

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“…Two additional modules are implemented within RIM-BAY, broadening its versatility: first, the water layer concept, developed by Goeller et al (2013a), providing a sophisticated concept for the evolution of a large-scale subglacial hydrological network, which interacts with the ice sheet by modifying the basal boundary conditions. Second, a sub-grid scale Lagrangian-tracer module, allowing to track tracer propagation through the ice, which assists with the interpretation of the origin and age of ice cores (Sutter et al, 2013).…”

Section: Discussionmentioning

confidence: 99%

RIMBAY – a multi-approximation 3D ice-dynamics model for comprehensive applications: model description and examples

et al. 2014

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Abstract. Glaciers and ice caps exhibit currently the largest cryospheric contributions to sea level rise. Modelling the dynamics and mass balance of the major ice sheets is therefore an important issue to investigate the current state and the future response of the cryosphere in response to changing environmental conditions, namely global warming. This requires a powerful, easy-to-use, versatile multi-approximation ice dynamics model. Based on the well-known and established ice sheet model of Pattyn (2003) we develop the modular multi-approximation thermomechanic ice model RIMBAY, in which we improve the original version in several aspects like a shallow ice-shallow shelf coupler and a full 3D-groundingline migration scheme based on Schoof's (2007) heuristic analytical approach. We summarise the full Stokes equations and several approximations implemented within this model and we describe the different numerical discretisations. The results are cross-validated against previous publications dealing with ice modelling, and some additional artificial set-ups demonstrate the robustness of the different solvers and their internal coupling. RIMBAY is designed for an easy adaption to new scientific issues. Hence, we demonstrate in very different set-ups the applicability and functionality of RIMBAY in Earth system science in general and ice modelling in particular.

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A balanced water layer concept for subglacial hydrology in large-scale ice sheet models

Cited by 30 publications

References 57 publications

Future sea-level rise due to projected ocean warming beneath the Filchner Ronne Ice Shelf: A coupled model study

Future sea-level rise due to projected ocean warming beneath the Filchner Ronne Ice Shelf: A coupled model study

A double continuum hydrological model for glacier applications

RIMBAY – a multi-approximation 3D ice-dynamics model for comprehensive applications: model description and examples

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