Subglacial melt channels and fracture in the floating part of Pine Island Glacier, Antarctica

Subglacial melt channels and fracture in the floating part of Pine Island Glacier, Antarctica

A dense grid of ice‐penetrating radar sections acquired over Pine Island Glacier, West Antarctica has revealed a network of sinuous subglacial channels, typically 500 m to 3 km wide, and up to 200 m high, in the ice‐shelf base. These subglacial channels develop while the ice is floating and result f...

Full description

Saved in:
Bibliographic Details
Published in:Journal of Geophysical Research: Earth Surface Vol. 117; no. F3
Main Authors: Vaughan, David G., Corr, Hugh F. J., Bindschadler, Robert A., Dutrieux, Pierre, Gudmundsson, G. Hilmar, Jenkins, Adrian, Newman, Thomas, Vornberger, Patricia, Wingham, Duncan J.
Format: Journal Article
Language:English
Published: Washington, DC Blackwell Publishing Ltd 01-09-2012
American Geophysical Union
Subjects:
Cryosphere
Earth sciences
Earth, ocean, space
Exact sciences and technology
fracture
Geology
Glaciers
ice shelf
Ice shelves
Ice thickness
Melting
ocean
Physical properties
Radar
Rocks
polar regions
West Antarctica
Antarctica
PSW, Antarctica, West Antarctica
PS, Antarctica
Antarctica, Ellsworth Land, Pine Island Glacier
glaciers
stress
Glacier crevasse
geologic sections
thickness
melting
ice
submersibles
finite element analysis
networks
Modeling
ice shelves
Thinning
channels
islands
Radar observation
Ice shelf
melts
radar methods
collapse
Comparative study
fractures
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:A dense grid of ice‐penetrating radar sections acquired over Pine Island Glacier, West Antarctica has revealed a network of sinuous subglacial channels, typically 500 m to 3 km wide, and up to 200 m high, in the ice‐shelf base. These subglacial channels develop while the ice is floating and result from melting at the base of the ice shelf. Above the apex of most channels, the radar shows isolated reflections from within the ice shelf. Comparison of the radar data with acoustic data obtained using an autonomous submersible, confirms that these echoes arise from open basal crevasses 50–100 m wide aligned with the subglacial channels and penetrating up to 1/3 of the ice thickness. Analogous sets of surface crevasses appear on the ridges between the basal channels. We suggest that both sets of crevasses were formed during the melting of the subglacial channels as a response to vertical flexing of the ice shelf toward the hydrostatic condition. Finite element modeling of stresses produced after the formation of idealized basal channels indicates that the stresses generated have the correct pattern and, if the channels were formed sufficiently rapidly, would have sufficient magnitude to explain the formation of the observed basal and surface crevasse sets. We conclude that ice‐shelf basal melting plays a role in determining patterns of surface and basal crevassing. Increased delivery of warm ocean water into the sub‐ice shelf cavity may therefore cause not only thinning but also structural weakening of the ice shelf, perhaps, as a prelude to eventual collapse. Key Points Ocean melting from an ice shelf base causes surface and basal crevassing Basal crevassing can be explained by finite‐element modeling Increased melting of ice shelves may eventually cause them to collapse
Bibliography:ark:/67375/WNG-QWC9Z5RL-R
ArticleID:2012JF002360
istex:4B362241BB00BFDC0A5D0C40210D0341EDAB51E3
ObjectType-Article-2
SourceType-Scholarly Journals-1
ObjectType-Feature-1
content type line 23
ISSN:0148-0227
2169-9003
2156-2202
2169-9011
DOI:10.1029/2012JF002360