Modeling channelized and distributed subglacial drainage in two dimensions

We present a two‐dimensional Glacier Drainage System model (GlaDS) that couples distributed and channelized subglacial water flow. Distributed flow occurs through linked cavities that are represented as a continuous water sheet of variable thickness. Channelized flow occurs through Röthlisberger cha...

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Bibliographic Details
Published in:Journal of geophysical research. Earth surface 2013-12, Vol.118 (4), p.2140-2158
Main Authors: Werder, Mauro A., Hewitt, Ian J., Schoof, Christian G., Flowers, Gwenn E.
Format: Article
Language:English
Subjects:
Channeling
Channels
Discharge
drainage network
Drainage systems
Earth science
Earth sciences
Earth, ocean, space
Exact sciences and technology
External geophysics
Freshwater
Geophysics
glacier drainage system
Glaciers
Glaciohydrology
glaciology
Hydrology
Hydrology. Hydrogeology
Mathematical models
Meltwater
modeling
Networks
self organized
Snow. Ice. Glaciers
subglacial drainage
Topology
Two dimensional
Water flow
Water storage
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Summary:We present a two‐dimensional Glacier Drainage System model (GlaDS) that couples distributed and channelized subglacial water flow. Distributed flow occurs through linked cavities that are represented as a continuous water sheet of variable thickness. Channelized flow occurs through Röthlisberger channels that can form on any of the edges of a prescribed, unstructured network of potential channels. Water storage is accounted for in an englacial aquifer and in moulins, which also act as point sources of water to the subglacial system. Solutions are presented for a synthetic topography designed to mimic an ice sheet margin. For low discharge, all the flow is accommodated in the sheet, whereas for sufficiently high discharge, the model exhibits a channelization instability which leads to the formation of a self‐organized channel system. The random orientation of the network edges allows the channel system geometry to be relatively unbiased, in contrast to previous structured grid‐based models. Under steady conditions, the model supports the classical view of the subglacial drainage system, with low pressure regions forming around the channels. Under diurnally varying input, water flows in and out of the channels, and a rather complex spatiotemporal pattern of water pressures is predicted. We explore the effects of parameter variations on the channel system topology and mean effective pressure. The model is then applied to a mountain glacier and forced with meltwater calculated by a temperature index model. The results are broadly consistent with our current understanding of the glacier drainage system and demonstrate the applicability of the model to real settings. Key Points Presenting a new 2D model of distributed and channelized subglacial drainage The channel system is generated as part of the model solution The applicability of the model to real settings is demonstrated
ISSN:2169-9003
2169-9011
DOI:10.1002/jgrf.20146