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Remote Sensing of the Ross Ice Streams and Adjacent Ross Ice Shelf, Antarctica

Bentley, C.R. ; Shabtaie, S. ; Blankenship, D.D. ; [et al.]

International Glaciological Society ; 1987

In: Annals of Glaciology Vol. 9 ( 1987), p. 20-29

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In: Annals of Glaciology, International Glaciological Society, Vol. 9 ( 1987), p. 20-29

Abstract: In the first few seasons of the Antarctic Siple Coast project, the University of Wisconsin has concentrated on radar and seismic studies. Highlights of the results to date include the delineation of ice streams A, B, and C and the ridges in between, determination of the surface elevations over the area, discovery of a much more advanced grounding line than previously recognized and recognition of a broad, flat, barely grounded “ice plain” just inside the grounding line. Complex zones between and adjoining some of the ice streams, characterized by an interspersal of undisturbed ice and crevassed patches, give the impression of being transformed from sheet flow into stream flow in a process of ice stream expansion. An indicated negative mass balance for ice stream B could be the result of this “activation” process. Ice stream C, currently stagnant, exhibits terraces and reversals of surface slope, associated with zones of strong, steady basal radar reflections. These features suggest that subglacial water has been trapped by reversals in the hydraulic pressure gradient. Low seismic P-wave and S-wave velocities in a meters-thick layer immediately below the ice strongly indicate a saturated sediment of such high porosity (~40%) and low effective (differential) pressure (~50 kPa, or 0.5% of the glaciostatic pressure) that it must be too weak not to be deforming. We presume this deforming layer to be a dilated till. Its base exhibits ridges and troughs parallel to the flow direction that resemble glacial megaflutes. We believe that at our site on the upper part of ice stream B the ice stream moves principally by deforming its bed. Analysis of seismographic recordings of micro-earthquakes that occur at the glacier bed shows that the micro-earthquakes are both small in energy and infrequent. This implies that virtually none of the energy of ice stream motion is dissipated by brittle fracture at the bed. If our models are correct, the subgiacial deforming till becomes increasingly soft down-glacier, and/or the ice becomes decoupled from the till by intervening water, until on the “ice plain” basal drag is less important than longitudinal stresses in the dynamic balance. Our models also imply that the “ice plains” rest on “till deltas” that have been formed by the deposition of till carried along beneath the ice streams, and that the till deltas, and the grounding lines that bound them, are currently advancing in front of the active ice streams.

Type of Medium: Online Resource

ISSN: 0260-3055 , 1727-5644

URL: Article

DOI: 10.1017/S026030550000032X

Language: English

Publisher: International Glaciological Society

Publication Date: 1987

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Remote Sensing of the Ross Ice Streams and Adjacent Ross Ice Shelf, Antarctica

Bentley, C.R. ; Shabtaie, S. ; Blankenship, D.D. ; [et al.]

International Glaciological Society ; 1987

In: Annals of Glaciology Vol. 9 ( 1987), p. 20-29

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In: Annals of Glaciology, International Glaciological Society, Vol. 9 ( 1987), p. 20-29

Abstract: In the first few seasons of the Antarctic Siple Coast project, the University of Wisconsin has concentrated on radar and seismic studies. Highlights of the results to date include the delineation of ice streams A, B, and C and the ridges in between, determination of the surface elevations over the area, discovery of a much more advanced grounding line than previously recognized and recognition of a broad, flat, barely grounded “ice plain” just inside the grounding line. Complex zones between and adjoining some of the ice streams, characterized by an interspersal of undisturbed ice and crevassed patches, give the impression of being transformed from sheet flow into stream flow in a process of ice stream expansion. An indicated negative mass balance for ice stream B could be the result of this “activation” process. Ice stream C, currently stagnant, exhibits terraces and reversals of surface slope, associated with zones of strong, steady basal radar reflections. These features suggest that subglacial water has been trapped by reversals in the hydraulic pressure gradient. Low seismic P-wave and S-wave velocities in a meters-thick layer immediately below the ice strongly indicate a saturated sediment of such high porosity (~40%) and low effective (differential) pressure (~50 kPa, or 0.5% of the glaciostatic pressure) that it must be too weak not to be deforming. We presume this deforming layer to be a dilated till. Its base exhibits ridges and troughs parallel to the flow direction that resemble glacial megaflutes. We believe that at our site on the upper part of ice stream B the ice stream moves principally by deforming its bed. Analysis of seismographic recordings of micro-earthquakes that occur at the glacier bed shows that the micro-earthquakes are both small in energy and infrequent. This implies that virtually none of the energy of ice stream motion is dissipated by brittle fracture at the bed. If our models are correct, the subgiacial deforming till becomes increasingly soft down-glacier, and/or the ice becomes decoupled from the till by intervening water, until on the “ice plain” basal drag is less important than longitudinal stresses in the dynamic balance. Our models also imply that the “ice plains” rest on “till deltas” that have been formed by the deposition of till carried along beneath the ice streams, and that the till deltas, and the grounding lines that bound them, are currently advancing in front of the active ice streams.

Type of Medium: Online Resource

ISSN: 0260-3055 , 1727-5644

URL: Article

DOI: 10.3189/S0260305500200700

Language: English

Publisher: International Glaciological Society

Publication Date: 1987

detail.hit.zdb_id: 2122400-6

SSG: 14

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3

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Remote Sensing of the Ross Ice Streams and Adjacent Ross Ice Shelf, Antarctica

Bentley, C.R. ; Shabtaie, S. ; Blankenship, D.D. ; [et al.]

International Glaciological Society ; 1987

In: Annals of Glaciology Vol. 9 ( 1987), p. 20-29

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In: Annals of Glaciology, International Glaciological Society, Vol. 9 ( 1987), p. 20-29

Abstract: In the first few seasons of the Antarctic Siple Coast project, the University of Wisconsin has concentrated on radar and seismic studies. Highlights of the results to date include the delineation of ice streams A, B, and C and the ridges in between, determination of the surface elevations over the area, discovery of a much more advanced grounding line than previously recognized and recognition of a broad, flat, barely grounded “ice plain” just inside the grounding line. Complex zones between and adjoining some of the ice streams, characterized by an interspersal of undisturbed ice and crevassed patches, give the impression of being transformed from sheet flow into stream flow in a process of ice stream expansion. An indicated negative mass balance for ice stream B could be the result of this “activation” process. Ice stream C, currently stagnant, exhibits terraces and reversals of surface slope, associated with zones of strong, steady basal radar reflections. These features suggest that subglacial water has been trapped by reversals in the hydraulic pressure gradient. Low seismic P-wave and S-wave velocities in a meters-thick layer immediately below the ice strongly indicate a saturated sediment of such high porosity (~40%) and low effective (differential) pressure (~50 kPa, or 0.5% of the glaciostatic pressure) that it must be too weak not to be deforming. We presume this deforming layer to be a dilated till. Its base exhibits ridges and troughs parallel to the flow direction that resemble glacial megaflutes. We believe that at our site on the upper part of ice stream B the ice stream moves principally by deforming its bed. Analysis of seismographic recordings of micro-earthquakes that occur at the glacier bed shows that the micro-earthquakes are both small in energy and infrequent. This implies that virtually none of the energy of ice stream motion is dissipated by brittle fracture at the bed. If our models are correct, the subgiacial deforming till becomes increasingly soft down-glacier, and/or the ice becomes decoupled from the till by intervening water, until on the “ice plain” basal drag is less important than longitudinal stresses in the dynamic balance. Our models also imply that the “ice plains” rest on “till deltas” that have been formed by the deposition of till carried along beneath the ice streams, and that the till deltas, and the grounding lines that bound them, are currently advancing in front of the active ice streams.

Type of Medium: Online Resource

ISSN: 0260-3055 , 1727-5644

URL: Article

DOI: 10.1017/S0260305500200700

Language: English

Publisher: International Glaciological Society

Publication Date: 1987

detail.hit.zdb_id: 2122400-6

SSG: 14

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4

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Ice Stream C, Antarctica, sticky spots detected by microearthquake monitoring

Anandakrishnan, S. ; Alley, R. B.

International Glaciological Society ; 1994

In: Annals of Glaciology Vol. 20 ( 1994), p. 183-186

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In: Annals of Glaciology, International Glaciological Society, Vol. 20 ( 1994), p. 183-186

Abstract: Microearthquakes at the base of slow-moving Ice Stream C occur many times more frequently than at the base of fast-moving Ice Stream B. We suggest that the microearthquake source sites are so-called “sticky spots”, defined as limited zones of stronger Subglacial material interspersed within a weaker matrix. The fault-plane area of the microearthquakes ( O (10 2 m 2 )) is therefore a measure of the size of the sticky spots. The spatial density of the microearthquakes ( O (10 km -2 )) is a measure of the distribution of sticky spots. The average stress drop associated with these microearthquakes is consistent with an ice-stream bed model of weak subglacial till interspersed with stronger zones that support much or all of the basal shear stress. We infer a weak inter-sticky-spot material by the large distances ( O (10 3 m)), relative to fault radius, to which the microearthquake stress change is transmitted.

Type of Medium: Online Resource

ISSN: 0260-3055 , 1727-5644

URL: Article

DOI: 10.3189/1994AoG20-1-183-186

Language: English

Publisher: International Glaciological Society

Publication Date: 1994

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5

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Density-Depth Profile Determined by Seismic-Refraction Studies: Ice Stream B. West Antarctica (Abstract)

Anandakrishnan, S.

International Glaciological Society ; 1988

In: Annals of Glaciology Vol. 11 ( 1988), p. 198-

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In: Annals of Glaciology, International Glaciological Society, Vol. 11 ( 1988), p. 198-

Abstract: Detailed seismic short-refraction profiling was conducted on Ice Stream Β (UpB) during the 1983–84 austral summer. A new high-resolution data logger, developed at the University of Wisconsin, recorded both compressional- and shear-wave arrivals. We report here on P-wave and S-wave profiles recorded along a line parallel to the axis of the ice stream. Source-receiver separations up to 720 m yielded seismic velocity-depth curves to below the firn-ice transition zone (slightly greater than 30 m at UpB). For the compressional-wave profile, geophones were separated by 2.5 m, which yielded a velocity-depth curve with a granularity of ∼1 m. The corresponding density-depth curve agrees well with direct density measurements obtained from a core extracted nearby (Alley and Bentley 1988, this volume). Discontinuities in the velocity gradient do not appear at the “critical densities” as they did at Byrd Station, Antarctica, and elsewhere (Kohnen and Bentley 1973 , Robertson and Bentley 1975). Two shear-wave profiles were recorded, both with geophone spacings of 5 m, one with longitudinal polarization (SV) and the other with transverse polarization (SH). There is a marked difference in velocity between the SH and SV waves, particularly in the shallow firn. We suggest that a strong vertical shape-and-bonding fabric in the shallow firn, as observed in cores collected at UpB, would account for this disparity.

Type of Medium: Online Resource

ISSN: 0260-3055 , 1727-5644

URL: Article

DOI: 10.1017/S0260305500006546

Language: English

Publisher: International Glaciological Society

Publication Date: 1988

detail.hit.zdb_id: 2122400-6

SSG: 14

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6

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Density-Depth Profile Determined by Seismic-Refraction Studies: Ice Stream B. West Antarctica (Abstract)

Anandakrishnan, S. ; Blankenship, D. D. ; Alley, R. B. ; [et al.]

International Glaciological Society ; 1988

In: Annals of Glaciology Vol. 11 ( 1988), p. 198-198

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In: Annals of Glaciology, International Glaciological Society, Vol. 11 ( 1988), p. 198-198

Abstract: Detailed seismic short-refraction profiling was conducted on Ice Stream Β (UpB) during the 1983–84 austral summer. A new high-resolution data logger, developed at the University of Wisconsin, recorded both compressional- and shear-wave arrivals. We report here on P-wave and S-wave profiles recorded along a line parallel to the axis of the ice stream. Source-receiver separations up to 720 m yielded seismic velocity-depth curves to below the firn-ice transition zone (slightly greater than 30 m at UpB). For the compressional-wave profile, geophones were separated by 2.5 m, which yielded a velocity-depth curve with a granularity of ∼1 m. The corresponding density-depth curve agrees well with direct density measurements obtained from a core extracted nearby (Alley and Bentley 1988, this volume). Discontinuities in the velocity gradient do not appear at the “critical densities” as they did at Byrd Station, Antarctica, and elsewhere (Kohnen and Bentley 1973, Robertson and Bentley 1975). Two shear-wave profiles were recorded, both with geophone spacings of 5 m, one with longitudinal polarization (SV) and the other with transverse polarization (SH). There is a marked difference in velocity between the SH and SV waves, particularly in the shallow firn. We suggest that a strong vertical shape-and-bonding fabric in the shallow firn, as observed in cores collected at UpB, would account for this disparity.

Type of Medium: Online Resource

ISSN: 0260-3055 , 1727-5644

URL: Article

DOI: 10.3189/S0260305500006546

Language: English

Publisher: International Glaciological Society

Publication Date: 1988

detail.hit.zdb_id: 2122400-6

SSG: 14

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7

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

Anandakrishnan, S. ; Bentley, C. R.

International Glaciological Society ; 1993

In: Journal of Glaciology Vol. 39, No. 133 ( 1993), p. 455-462

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In: Journal of Glaciology, International Glaciological Society, Vol. 39, No. 133 ( 1993), p. 455-462

Abstract: Micro-earthquakes have been monitored at two locations on Ice Stream Β and one on Ice Stream C using a seismographic array built specifically for that purpose. Subglacial micro-earthquakes arc 20 times more abundant beneath Ice Stream C than beneath Ice Stream B, despite the 100 times more rapid movement of Ice Stream B. Triangulation shows the foci beneath Ice Stream C, like those beneath Ice Stream B, to be within a few meters of the base of the ice, presumably within the uppermost part of the bed, and fault-plane analysis indicates slips on horizontal planes at about a 30° angle to the presumed direction of formerly active flow. Source parameters, computed from spectra of the arrivals, confirmed that the speed of slip is three orders of magnitude faster beneath Ice Stream C than beneath Ice Stream Β which means that a five orders-of-magnitude greater fraction of the velocity of Ice Stream C is contributed by the faulting, although that fraction is still small. We attribute the difference in activity beneath the two ice streams to the loss of dilatancy in the till beneath Ice Stream C in the process that led to its stagnation.

Type of Medium: Online Resource

ISSN: 0022-1430 , 1727-5652

URL: Article

DOI: 10.3189/S0022143000016348

Language: English

Publisher: International Glaciological Society

Publication Date: 1993

detail.hit.zdb_id: 2140541-4

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8

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Microearthquake Source Locations and Mechanisms: Ice Stream B, West Antarctica (Abstract)

Anandakrishnan, S. ; Blankenship, D. D. ; Bentley, C. R.

International Glaciological Society ; 1988

In: Annals of Glaciology Vol. 11 ( 1988), p. 199-199

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In: Annals of Glaciology, International Glaciological Society, Vol. 11 ( 1988), p. 199-199

Abstract: An array of nine seismographic stations, each sensitive to all three components of motion, was deployed on Ice Stream B, West Antarctica, during the austral summer of 1985–86. The network was sensitive to high-frequency (=400 Hz) seismic activity within a 350 km 2 area of the ice stream, and the deployment geometry allows the precise determination of depths for events beneath the 10 km 2 array. Microearthquakes from both beneath and beside the ice stream were detected and recorded (Blankenship and others 1987). Inversion of P-wave and S-wave travel times and radiation patterns allows the determination of locations and fault-plane solutions for many of these events. We find that bottom events involve low-angle thrusting, in the down-stream direction, of ice or till; displacement is ∼½ cm per event over a (15 m) 2 area. Such faulting is rare and releases an insignificant part of the total energy dissipated by ice flow. However, this is a possible mechanism for plucking of the ice-stream bed. Fault-plane solutions for most major surface events are consistent with the opening of tensional fractures oriented transverse to ice flow. Precise location of these events shows that they correspond to open crevasses, mapped by Vornberger and Whillans (1986), that are oriented transverse to ice flow. In addition, shear-wave splitting observed on some of the microearthquakes shows that the c -axes in the ice stream are slightly, but not strongly, anisotropic. Precise location of the sources requires the use of a detailed velocity-depth profile in the firn, which was obtained by seismic short-refraction studies (Anandakrishnan and others 1988, this volume). A density-depth profile calculated from these velocities agrees well with direct density measurements on a single core nearby (Alley and Bentley 1988, this volume).

Type of Medium: Online Resource

ISSN: 0260-3055 , 1727-5644

URL: Article

DOI: 10.3189/S0260305500006558

Language: English

Publisher: International Glaciological Society

Publication Date: 1988

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9

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Microearthquakes Under and Alongside Ice Stream B, Antarctica. Detected By A New Passive Seismic Array

Blankenship, D.D. ; Anandakrishnan, S. ; Kempf, J.L. ; [et al.]

International Glaciological Society ; 1987

In: Annals of Glaciology Vol. 9 ( 1987), p. 30-34

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In: Annals of Glaciology, International Glaciological Society, Vol. 9 ( 1987), p. 30-34

Abstract: A new seismographic array with a band width of 500 Hz per channel and a dynamic range of 96 dB was developed for detecting natural events on glaciers. It was first deployed on ice stream B during the 1985–86 austral summer. The network consists of nine solar-powered seismographs, each monitoring three components of ground motion. Each of the seismographs is connected by up to 4 km of fiber-optic cable to a central node where seismic events are both detected and recorded. During 85 h of passive seismic monitoring on ice stream B, 25 microearthquakes were observed. Sixteen of these events were associated with shallow crevassing, mostly near the margins, although not within the zones of extreme shearing that bound the ice streams. Nine microearthquakes were associated with low-angle thrusting near the base of the ice stream. The principal initial result of these passive seismic studies is the demonstration that virtually none of the energy dissipated beneath ice stream B takes place through brittle fracture near the base. Nevertheless, fracture associated with microearthquakes may play a significant role in sub-glacial erosion.

Type of Medium: Online Resource

ISSN: 0260-3055 , 1727-5644

URL: Article

DOI: 10.1017/S0260305500200712

Language: English

Publisher: International Glaciological Society

Publication Date: 1987

detail.hit.zdb_id: 2122400-6

SSG: 14

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10

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Microearthquakes Under and Alongside Ice Stream B, Antarctica. Detected By A New Passive Seismic Array

Blankenship, D.D. ; Anandakrishnan, S. ; Kempf, J.L. ; [et al.]

International Glaciological Society ; 1987

In: Annals of Glaciology Vol. 9 ( 1987), p. 30-34

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In: Annals of Glaciology, International Glaciological Society, Vol. 9 ( 1987), p. 30-34

Abstract: A new seismographic array with a band width of 500 Hz per channel and a dynamic range of 96 dB was developed for detecting natural events on glaciers. It was first deployed on ice stream B during the 1985–86 austral summer. The network consists of nine solar-powered seismographs, each monitoring three components of ground motion. Each of the seismographs is connected by up to 4 km of fiber-optic cable to a central node where seismic events are both detected and recorded. During 85 h of passive seismic monitoring on ice stream B, 25 microearthquakes were observed. Sixteen of these events were associated with shallow crevassing, mostly near the margins, although not within the zones of extreme shearing that bound the ice streams. Nine microearthquakes were associated with low-angle thrusting near the base of the ice stream. The principal initial result of these passive seismic studies is the demonstration that virtually none of the energy dissipated beneath ice stream B takes place through brittle fracture near the base. Nevertheless, fracture associated with microearthquakes may play a significant role in sub-glacial erosion.

Type of Medium: Online Resource

ISSN: 0260-3055 , 1727-5644

URL: Article

DOI: 10.3189/S0260305500200712

Language: English

Publisher: International Glaciological Society

Publication Date: 1987

detail.hit.zdb_id: 2122400-6

SSG: 14

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