Micro-earthquakes beneath Ice Streams Β and C, West Antarctica: observations and implications

Anandakrishnan, S.; Bentley, C. R.

doi:10.3189/s0022143000016348

Cited by 73 publications

(115 citation statements)

References 27 publications

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“…High‐frequency seismic signals associated with glaciated environments have been recorded in Greenland, Antarctica, and Alaska and are known to be complex (e.g., Amundson et al, ; Anandakrishnan & Bentley, ; MacAyeal et al, ; O'Neel et al, ; Rial et al, ). High‐frequency seismic signals originate from stick‐slip motion at the ice‐bed interface in Western Greenland (Röösli, Helmstetter, et al, ) but generate higher frequencies (20–200 Hz) than we observe and appear to be observable only at very short distances.…”

Section: Discussionmentioning

confidence: 99%

Constraints on Terminus Dynamics at Greenland Glaciers From Small Glacial Earthquakes

Olsen

Nettles

2019

JGR Earth Surface

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Many large calving events at Greenland's marine-terminating glaciers generate globally detectable glacial earthquakes. We perform a cross-correlation analysis using regional seismic data to identify events below the teleseismic detection threshold, focusing on the 24 hr surrounding known glacial earthquakes at Greenland's three largest glaciers. We detect additional seismic events in the minutes prior to more than half of the glacial earthquakes we study and following one third of them. Waveform modeling shows source mechanisms like those of previously known glacial earthquakes, a result consistent with available imagery. The seismic events thus do not represent a failure of the high subaerial ice cliff like that expected to trigger large-scale calving and a marine ice-cliff instability but, rather, rotational, buoyancy-driven calving events, likely of the full glacier thickness. A limited investigation of the prevalence of smaller seismic events at times outside glacial-earthquake windows identifies several additional events. However, we find that calving at the three glaciers we study-Jakobshavn Isbrae, Helheim Glacier, and Kangerdlugssuaq Glacier-often occurs as sequences of discrete buoyancy-driven events in which multiple icebergs ranging in size over as much as three orders of magnitude are all lost within ∼30 min. We demonstrate a correlation between glacial-earthquake magnitude and iceberg size for events with well-constrained iceberg-area estimates. Our results suggest that at least 10-30% more dynamic mass loss occurs through buoyancy-driven calving at Greenland's glaciers than previously appreciated.

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Section: Discussionmentioning

confidence: 99%

Constraints on Terminus Dynamics at Greenland Glaciers From Small Glacial Earthquakes

Olsen

Nettles

2019

JGR Earth Surface

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“…In addition to impulsive events that are typically recorded on ice streams [ Anandakrishnan and Bentley , 1993; Smith , 2006], we recorded two events, which we refer to as harmonic‐tremor events, of a type that has not been previously reported from Antarctica (Figures 2a and 2b). The events occurred two weeks apart (on days 348 and 365 of 2005), and are distinguished by: 1) durations of approximately 10 minutes, and 2) nearly monochromatic energy centered at a frequency of 3 Hz (Figure 2).…”

Section: Seismic Observations Of Glacial Tremormentioning

confidence: 96%

“…As we argue below, a subglacial outburst flood that drained from one lake to a second lake can explain these phenomena. Subglacial icequakes that are generated by stick‐slip basal motion produce impulsive broadband signals [ Anandakrishnan and Bentley , 1993], and ordinary crevassing events are also broadband sources [ Deichmann et al , 2000], both inconsistent with the observed tremors. In contrast, the long‐duration monochromatic nature of the MacIS tremors is similar to harmonic tremors observed in volcanic settings that originate from the resonance of magma‐filled conduits [ Chouet et al , 1994; Julian , 1994].…”

Section: Source Mechanismmentioning

confidence: 99%

Seismic observations of transient subglacial water‐flow beneath MacAyeal Ice Stream, West Antarctica

Winberry

Anandakrishnan

Alley

2009

Geophysical Research Letters

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[1] New seismic observations of harmonic tremors beneath MacAyeal Ice Stream, West Antarctica are reported. Each of the two tremor events that we recorded during a six week period had sustained arrival of 3 Hz energy for approximately 10 minutes. During that time the source location migrated a few kilometers. The harmonic nature of the tremors is interpreted as the result of resonance in subglacial water-filled cracks and conduits. The duration, monochromatic nature, and movement of the tremor indicate that the source mechanism is likely flow in the subglacial water system resulting from the discharge from a small subglacial lake. Our results suggest that the subglacial water system produces repeated, small outburst floods, with possible implications for ice-stream dynamics.

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“…The stick‐slip events can be triggered by stress changes through the tidal‐influenced floating ice shelves [e.g., Zoet et al , ; Winberry et al , ] or by lateral changes in till rheology [ Smith et al , ]. Both long‐duration slip events (lasting tens of minutes) [e.g., Winberry et al , ; Walter et al , ] and microseismicity (lasting fractions of a second) in the form of basal icequakes [e.g., Blankenship et al , ; Anandakrishnan and Bentley , ; Smith , ; Danesi et al , ] indicate that we need to consider coseismic slip in addition to viscous flow and basal sliding in the physical models for ice stream flow [ Goldberg et al , ; Tsai et al , ].…”

Section: Introductionmentioning

confidence: 99%

Meltwater influences on deep stick‐slip icequakes near the base of the Greenland Ice Sheet

et al. 2016

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We detected over 11,000 stick-slip icequakes near the base of the western margin of the Greenland Ice Sheet using a 17-seismometer array. These icequakes have negative (i.e., very small) moment magnitudes and, according to similarities in their waveforms, group into over 100 distinct clusters distributed beneath our 3 × 3 km study area. Some clusters were active for several weeks, while others have burst-like episodes lasting 1-6 days only. Some clusters correlate with subglacial water pressure measured within a nearby moulin. For these clusters, we observe high water pressure concurrent with many small yet numerous stick-slip icequakes and periods of lower water pressures with larger, less frequent icequakes. These patterns might change over time and are not common to all clusters. We explain these observations that the stick-slip icequakes are located at sticky spots at the interface of the ice sheet with the glacier bed that consists of basal till characterized by different connectivity to the subglacial drainage system. Because the till's frictional strength depends on its pore pressure, variations in subglacial water pressure can either weaken or strengthen the bed; this explains the variation in seismic moments and interevent times. Our results suggest that seismogenic stick-slip motion is an integral part of the flow mechanism in the ablation zone in western Greenland, which is highly sensitive to the configuration of the local subglacial drainage system. Stick-slip motion may therefore play a key role in the relationship between climate-induced changes of surface runoff and ice sheet dynamics.

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Micro-earthquakes beneath Ice Streams Β and C, West Antarctica: observations and implications

Cited by 73 publications

References 27 publications

Constraints on Terminus Dynamics at Greenland Glaciers From Small Glacial Earthquakes

Constraints on Terminus Dynamics at Greenland Glaciers From Small Glacial Earthquakes

Seismic observations of transient subglacial water‐flow beneath MacAyeal Ice Stream, West Antarctica

Meltwater influences on deep stick‐slip icequakes near the base of the Greenland Ice Sheet

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