Glacier slip and seismicity induced by surface melt

Many of the key processes governing fast glacier flow involve interaction between a glacier and its basal hydrological system, which is hidden from direct observation. Passive seismic monitoring has shown promise as a tool for remotely monitoring basal processes, but lack of glacier-bed access preve...

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Bibliographic Details
Main Authors: Moore, Peter L., Winberry, J. Paul, Iverson, Neal R., Christianson, Knut A., Anandakrishnan, Sridhar, Jackson, Miriam, Mathison, Mark E., Cohen, Denis
Format: Text
Language:unknown
Published: ScholarWorks@CWU 2013
Subjects:
acoustical emissions
bedrock
deformation
Europe
flows
geophysical methods
glacial geology
glaciers
hydrology
ice movement
Norway
Scandinavia
seismic methods
seismicity
shear stress
subglacial processes
water pressure
Western Europe
Svartisen ice cap
Engabreen Glacier
Geology
Geomorphology
Geophysics and Seismology
Glaciology
Tectonics and Structure
Engabreen
Svartisen
glacier
Ice cap
Online Access:https://digitalcommons.cwu.edu/cotsfac/321
https://digitalcommons.cwu.edu/cgi/viewcontent.cgi?article=1321&context=cotsfac
Description
Summary:Many of the key processes governing fast glacier flow involve interaction between a glacier and its basal hydrological system, which is hidden from direct observation. Passive seismic monitoring has shown promise as a tool for remotely monitoring basal processes, but lack of glacier-bed access prevents clear understanding of the relationships between subglacial processes and corresponding seismic emissions. Here we describe direct measurements of basal hydrology, sliding, and broadband seismicity made in a unique subglacial facility in Norway during the onset of two summer melt seasons. In the most pronounced of these episodes, rapid delivery of surface meltwater to the bed briefly enhanced basal slip following a period of elevated high-frequency seismic activity related to surface crevassing. Subsequent ground tilt derived from ultralong-period seismic signals was associated with subglacial bedrock deformation during transient pressurization of the basal hydraulic system. These signals are interpreted to represent hydraulic jacking as the supply of water to the bed exceeded the capacity of the hydraulic system. Enhanced slip terminated 2.5 h after it started, when ice-bed decoupling or increased connectivity in the basal cavity network relieved cavity overpressure. The results support theoretical models for hydraulic jacking and illustrate how melt-induced increases in speed can be short lived if cavity growth or ice-bed decoupling allows basal water more efficient drainage.

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