A unified model for transient subglacial water pressure and basal sliding

Abstract Changes in water pressure at the beds of glaciers greatly modify their sliding rate, affecting rates of ice mass loss and sea level change. However, there is still no agreement about the physics of subglacial sliding or how water affects it. Here, we present a new simplified physical model for the effect of transient subglacial hydrology on basal ice velocity. This model assumes that a fraction of the glacier bed is connected by an active hydrologic system that, when averaged over an appropriate scale, is governed by two parameters with limited spatial variability. The sliding model is reminiscent of Budd's empirical sliding law but with fundamental differences including a dependence on the fractional area of the active hydrologic system. With periodic surface meltwater forcing, the model displays classic diffusion-wave behavior, with a downstream time lag and decay of subglacial water pressure perturbations. Testing the model against Greenland observations suggests that, despite its simplicity, it captures key features of observed proglacial discharges and ice velocities with reasonable physical parameter values. Given these encouraging findings, including this sliding model in predictive ice-sheet models may improve their ability to predict time-evolving velocities and associated sea level change and reduce the related uncertainties.

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Ice-mass changes in Aurora basin, East Antarctica, in coupled and uncoupled ice-ocean simulations

10.5194/egusphere-egu21-13707 ◽

2021 ◽

Author(s):

Konstanze Haubner ◽

Guillian Van Achter ◽

Charles Pelletier ◽

Lars Zipf ◽

Thierry Fichefet ◽

...

Keyword(s):

Sea Level ◽

Ocean Circulation ◽

Ice Sheet ◽

Sea Level Change ◽

Coupling Scheme ◽

Coupled Models ◽

Level Change ◽

Ice Velocity ◽

Velocity Changes ◽

Global Sea Level

Ice mass loss of Greenland and Antarctic ice sheets is a major contributor to sea level change with an expected major impact on the world's infrastructures over the next decades. Therefore, precise estimates of sea level change are needed. However, estimates of future changes in sea level are either provided by earth system models, which rarely include ice sheet models, or by standalone ice sheet models. Hence, feedbacks between ice and atmosphere-ocean are overseen. Local scale coupled models help bridging this gap by estimating how feedbacks between the different earth systems affect global sea level estimates.Here, we present results from a coupled simulation of the ocean-sea ice model NEMO3.6-LIM3 (1/24&#176; grid ~ less than 2 km grid spacing) and the ice sheet model BISICLES (on 0.5 - 4km spatial resolution). The coupling routine is done via python code including variable exchange, pre- and post-processing, done offline every 3 months.Simulated ice mass changes, grounding line position and ice velocity changes of this high-resolution coupling scheme (between 1993-2014) are compared to observations and results of uncoupled simulations. We further discuss which processes might be neglectable and which are the main drivers of ice velocity acceleration and changes in sub-shelf ocean circulation.

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Significant continental ice volumes on mid-Paleocene Antarctica? Latitudinal temperature gradients, sea level change and the carbon cycle

Rendiconti online della Società Geologica Italiana ◽

10.3301/rol.2014.30 ◽

2014 ◽

Vol 31 ◽

pp. 31-32

Author(s):

Peter Bijl

Keyword(s):

Carbon Cycle ◽

Sea Level ◽

Sea Level Change ◽

Temperature Gradients ◽

Level Change

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Phanerozoic Oxygen

10.23943/princeton/9780691145020.003.0011 ◽

2017 ◽

Author(s):

Donald Eugene Canfield

Keyword(s):

Oxygen Consumption ◽

Organic Carbon ◽

Sea Level ◽

Time Scale ◽

Atmospheric Oxygen ◽

Sea Level Change ◽

Oxygen Production ◽

Level Change ◽

History Of ◽

Geologic Processes

This chapter discusses the modeling of the history of atmospheric oxygen. The most recently deposited sediments will also be the most prone to weathering through processes like sea-level change or uplift of the land. Thus, through rapid recycling, high rates of oxygen production through the burial of organic-rich sediments will quickly lead to high rates of oxygen consumption through the exposure of these organic-rich sediments to weathering. From a modeling perspective, rapid recycling helps to dampen oxygen changes. This is important because the fluxes of oxygen through the atmosphere during organic carbon and pyrite burial, and by weathering, are huge compared to the relatively small amounts of oxygen in the atmosphere. Thus, all of the oxygen in the present atmosphere is cycled through geologic processes of oxygen liberation (organic carbon and pyrite burial) and consumption (weathering) on a time scale of about 2 to 3 million years.

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