2016
DOI: 10.1002/2016rg000526
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Cryoseismology

Abstract: The last decade witnessed an explosion in yearly number of publications on passive glacier seismology. The seismic signals from a wide range of glacier‐related processes fill a broad band of frequencies (from 10−3 to 102 Hz) and moment magnitudes (from M–3 to M7) providing a fresh and unprecedented view on fundamental processes in the cryosphere. New insights into basal motion, iceberg calving, glacier, iceberg, and sea ice dynamics, and precursory signs of unstable glaciers and ice structural changes are bein… Show more

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Cited by 217 publications
(243 citation statements)
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References 328 publications
(840 reference statements)
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“…Several authors have developed physically based subglacial hydrological models accounting for some of these features (Schoof, 2010;Hewitt and others, 2012;Werder and others, 2013;Fleurian and others, 2014), but constraining them against observations is an arduous task as glacier beds are usually out of reach and traditionally used instruments, such as borehole pressure sensors (Schoof and others, 2014), provide limited spatial and temporal coverage. Although still at its premise, cryoseismology appears as a promising method to tackle this shortcoming in the near future (Gimbert and others, 2016;Podolskiy and Walter, 2016). At the same time, assuming that basal friction is governed by the Schoof law, observations of surface slopes at the GL and of GL retreat rates over a sufficiently large time window could give some insight on the distribution of basal water pressure.…”
Section: Discussionmentioning
confidence: 99%
“…Several authors have developed physically based subglacial hydrological models accounting for some of these features (Schoof, 2010;Hewitt and others, 2012;Werder and others, 2013;Fleurian and others, 2014), but constraining them against observations is an arduous task as glacier beds are usually out of reach and traditionally used instruments, such as borehole pressure sensors (Schoof and others, 2014), provide limited spatial and temporal coverage. Although still at its premise, cryoseismology appears as a promising method to tackle this shortcoming in the near future (Gimbert and others, 2016;Podolskiy and Walter, 2016). At the same time, assuming that basal friction is governed by the Schoof law, observations of surface slopes at the GL and of GL retreat rates over a sufficiently large time window could give some insight on the distribution of basal water pressure.…”
Section: Discussionmentioning
confidence: 99%
“…In the case of the active seismic and RES methods, considerable economic and logistical support is required to collect the data. With the rapid growth of cryo-seismology in the last one to two decades, many passive seismic methods have been applied to cryospheric research (Podolskiy and Walter, 2016;Aster and Winberry, 2017). Given that passive seismic methods can mitigate logistical problem and are relatively cost-efficient (Zhan et al, 2014;Picotti et al, 2017), it is therefore of interest to explore the feasibility of passive seismic methods to contribute additional and/or better constraints to the ice sheet structure.…”
Section: Introductionmentioning
confidence: 99%
“…They are associated with repetitive stick-slip events on the fracture plane. Tensile fracture opening/closing generate similar signals on glacier at the surface and at depth (Walter et al, 2013a;Helmstetter et al, 2015b;Podolskiy and Walter, 2016). Focal mechanism and location of the source allow to differentiate between tensile and shear mechanism.…”
mentioning
confidence: 99%
“…This variety of signals are observed during glacier motion. Deep icequakes are usually associated to basal motion (Winberry et al, 2011;Pratt et al, 2014;25 Helmstetter et al, 2015a, b;Röösli et al, 2016a;Podolskiy and Walter, 2016). Tremor like signals are also recorded during glacier motion (Lipovsky and Dunham, 2016).…”
mentioning
confidence: 99%