Implementation of higher-order vertical finite elements in ISSM v4.13.
for improved ice sheet flow modeling over paleoclimate timescales

Cuzzone, Joshua; Morlighem, Mathieu; Larour, Eric; Schlegel, Nicole‐Jeanne; Seroussi, Hélène

doi:10.5194/gmd-2017-319

Cited by 4 publications

(5 citation statements)

References 30 publications

(46 reference statements)

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“…Despite these apparent problems, considerable progress has been made in numerical modeling of long‐term SLR. The Ice Sheet System Model, for example, has the advantage of an anisotropic mesh in order to better resolve grounding lines, but is nonetheless computationally cheap enough that it can also be used for millennial‐scale simulations (Åkesson, Nisancioglu, Giesen, & Morlighem, ; Cuzzone, Morlighem, Larour, Schlegel, & Seroussi, ). Many models now routinely use parallelized computation to run faster or higher‐resolution simulations (Aschwanden, Fahnestock, & Truffer, ; Bueler & Brown, ; Cuzzone et al, ; Martin et al, ).…”

Section: Advances and Future Directionsmentioning

confidence: 99%

“…The Ice Sheet System Model, for example, has the advantage of an anisotropic mesh in order to better resolve grounding lines, but is nonetheless computationally cheap enough that it can also be used for millennial‐scale simulations (Åkesson, Nisancioglu, Giesen, & Morlighem, ; Cuzzone, Morlighem, Larour, Schlegel, & Seroussi, ). Many models now routinely use parallelized computation to run faster or higher‐resolution simulations (Aschwanden, Fahnestock, & Truffer, ; Bueler & Brown, ; Cuzzone et al, ; Martin et al, ). Other groups have proposed the inclusion of processes such as ice shelf hydrofracture (Pollard et al, ), or use fully coupled simulations that better capture ice–ocean–atmosphere (Gierz, Lohmann, & Wei, ) or ice‐sheet–sea‐level (Gomez, Latychev, & Pollard, ) feedbacks.…”

Section: Advances and Future Directionsmentioning

confidence: 99%

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Long‐term projections of sea‐level rise from ice sheets

Golledge

2020

WIREs Climate Change

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Under future climate change scenarios it is virtually certain that global mean sea level will continue to rise. But the rate at which this occurs, and the height and time at which it might stabilize, are uncertain. The largest potential contributors to sea level are the Greenland and Antarctic ice sheets, but these may take thousands of years to fully adjust to environmental changes. Modeled projections of how these ice masses will evolve in the future are numerous, but vary both in complexity and projection timescale. Typically, there is greater agreement between models in the present century than over the next millennium. This reflects uncertainty in the physical processes that dominate icesheet change and also feedbacks in the ice-atmosphere-ocean system, and how these might lead to nonlinear behavior. Satellite observations help constrain short-term projections of ice-sheet change but these records are still too short to capture the full ice-sheet response. Conversely, geological records can be used to inform long-term ice-sheet simulations but are prone to large uncertainties, meaning that they are often unable to adequately confirm or refute the operation of particular processes. Because of these limitations there is a clear need to more accurately reconstruct sea level changes during periods of the past, to improve the spatial and temporal extent of current ice sheet observations, and to robustly attribute observed changes to driving mechanisms. Improved future projections will require models that capture a more extensive suite of physical processes than are presently incorporated, and which better quantify the associated uncertainties. This article is categorized under: Climate Models and Modeling > Knowledge Generation with Models K E Y W O R D S Antarctic, climate change, commitment, Greenland, ice sheet

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Section: Advances and Future Directionsmentioning

confidence: 99%

Section: Advances and Future Directionsmentioning

confidence: 99%

Long‐term projections of sea‐level rise from ice sheets

Golledge

2020

WIREs Climate Change

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“…We use linear P1 elements for the stress balance analysis and quadratic P2 elements for the thermal analysis. The P1P2 elements have been tested and validated in ISSM by Cuzzone et al (2018) and allow us to capture sharp thermal gradients, despite having only five layers.…”

Section: Model Forcing and Relaxationmentioning

confidence: 99%

Sensitivity of the Northeast Greenland Ice Stream to Geothermal Heat

et al. 2020

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Recent observations of ice flow surface velocities have helped improve our understanding of basal processes on Greenland and Antarctica, though these processes still constitute some of the largest uncertainties driving ice flow change today. The Northeast Greenland Ice Stream is driven largely by basal sliding, believed to be related to subglacial hydrology and the availability of heat. Characterization of the uncertainties associated with Northeast Greenland Ice Stream is crucial for constraining Greenland's potential contribution to sea level rise in the upcoming centuries. Here, we expand upon past work using the Ice Sheet System Model to quantify the uncertainties in models of the ice flow in the Northeast Greenland Ice Stream by perturbing the geothermal heat flux. Utilizing a subglacial hydrology model simulating sliding beneath the Greenland Ice Sheet, we investigate the sensitivity of the Northeast Greenland Ice Stream ice flow to various estimates of geothermal heat flux, and implications of basal heat flux uncertainties on modeling the hydrological processes beneath Greenland's major ice stream. We find that the uncertainty due to sliding at the bed is 10 times greater than the uncertainty associated with internal ice viscosity. Geothermal heat flux dictates the size of the area of the subglacial drainage system and its efficiency. The uncertainty of ice discharge from the Northeast Greenland Ice Stream to the ocean due to uncertainties in the geothermal heat flux is estimated at 2.10 Gt/yr. This highlights the urgency in obtaining better constraints on the highly uncertain subglacial hydrology parameters.

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“…However, for long transient runs and/or sensitivity analyses that require running the model for large ensembles, the HO model still demands relatively high computational resources. Recently, numerical schemes were applied to improve the computational efficiency of the HO model without compromising numerical accuracy (e.g., Langdon and Raymond, 1978;Bassis, 2010;Brinkerhoff and Johnson, 2015;Cuzzone et al, 2018;Shapero et al, 2021). These schemes rely on the finite element method (FEM), which allows the employment of polynomial functions of a degree equal to or greater than 2 to model the vertical variation in the horizontal velocities.…”

Section: Introductionmentioning

confidence: 99%

A new vertically integrated MOno-Layer Higher-Order (MOLHO) ice flow model

2022

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Abstract. Numerical simulations of ice sheets rely on the momentum balance to determine how ice velocities change as the geometry of the system evolves. Ice is generally assumed to follow a Stokes flow with a nonlinear viscosity. Several approximations have been proposed in order to lower the computational cost of a full-Stokes stress balance. A popular option is the Blatter–Pattyn or higher-order model (HO), which consists of a three-dimensional set of equations that solves the horizontal velocities only. However, it still remains computationally expensive for long transient simulations. Here we present a depth-integrated formulation of the HO model, which can be solved on a two-dimensional mesh in the horizontal plane. We employ a specific polynomial function to describe the vertical variation in the velocity, which allows us to integrate the vertical dimension using a semi-analytic integration. We assess the performance of this MOno-Layer Higher-Order (MOLHO) model to compute ice velocities and simulate grounding line dynamics on standard benchmarks (ISMIP-HOM and MISMIP3D). We compare MOLHO results to the ones obtained with the original three-dimensional HO model. We also compare the time performance of both models in time-dependent runs. Our results show that the ice velocities and grounding line positions obtained with MOLHO are in very good agreement with the ones from HO. In terms of computing time, MOLHO requires less than 10 % of the computational time of a typical HO model, for the same simulations. These results suggest that the MOno-Layer Higher-Order formulation provides improved computational time performance and a comparable accuracy compared to the HO formulation, which opens the door to higher-order paleo simulations.

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Implementation of higher-order vertical finite elements in ISSM v4.13. for improved ice sheet flow modeling over paleoclimate timescales

Cited by 4 publications

References 30 publications

Long‐term projections of sea‐level rise from ice sheets

Long‐term projections of sea‐level rise from ice sheets

Sensitivity of the Northeast Greenland Ice Stream to Geothermal Heat

A new vertically integrated MOno-Layer Higher-Order (MOLHO) ice flow model

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