WISSARD at Subglacial Lake Whillans, West Antarctica: Scientific operations and initial observations

Slawek Tulaczyk; Jill A. Mikucki; Matthew R. Siegfried; John C. Priscu; C. Grace Barcheck; Lucas H. Beem; Alberto Behar; Justin Burnett; Brent C. Christner; Andrew T. Fisher; Helen A. Fricker; Kenneth D. Mankoff; Ross D. Powell; Frank Rack; Daniel Sampson; Reed P. Scherer; Susan Y. Schwartz

doi:10.3189/2014AoG65A009

WISSARD at Subglacial Lake Whillans, West Antarctica: Scientific operations and initial observations

Slawek Tulaczyk, Jill A. Mikucki, Matthew R. Siegfried, John C. Priscu, C. Grace Barcheck, Lucas H. Beem, Alberto Behar, Justin Burnett, Brent C. Christner, Andrew T. Fisher, Helen A. Fricker, Kenneth D. Mankoff, Ross D. Powell, Frank Rack, Daniel Sampson, Reed P. Scherer, Susan Y. Schwartz

Research output: Chapter in Book/Report/Conference proceeding › Chapter

89 Scopus citations

Abstract

A clean hot-water drill was used to gain access to Subglacial Lake Whillans (SLW) in late January 2013 as part of theWhillans Ice Stream Subglacial Access Research Drilling (WISSARD) project. Over 3 days, we deployed an array of scientific tools through the SLW borehole: a downhole camera, a conductivity-temperature-depth (CTD) probe, a Niskin water sampler, an in situ filtration unit, three different sediment corers, a geothermal probe and a geophysical sensor string. Our observations confirm the existence of a subglacial water reservoir whose presence was previously inferred from satellite altimetry and surface geophysics. Subglacial water is about two orders of magnitude less saline than sea water (0.37-0.41 psu vs 35 psu) and two orders of magnitude more saline than pure drill meltwater (0.002 psu). It reaches a minimum temperature of -0.558C, consistent with depression of the freezing point by 7.019MPa of water pressure. Subglacial water was turbid and remained turbid following filtration through 0.45 mm filters. The recovered sediment cores, which sampled down to 0.8m below the lake bottom, contained a macroscopically structureless diamicton with shear strength between 2 and 6 kPa. Our main operational recommendation for future subglacial access through water-filled boreholes is to supply enough heat to the top of the borehole to keep it from freezing.

Original language	English (US)
Title of host publication	Annals of Glaciology
Publisher	International Glaciology Society
Pages	51-58
Number of pages	8
Volume	55
Edition	65
DOIs	https://doi.org/10.3189/2014AoG65A009
State	Published - Sep 1 2014
Externally published	Yes

Keywords

Antarctic glaciology
Ice streams
Subglacial lakes
Subglacial processes
Subglacial sediments

ASJC Scopus subject areas

Earth-Surface Processes

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10.3189/2014AoG65A009

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Tulaczyk, S., Mikucki, J. A., Siegfried, M. R., Priscu, J. C., Barcheck, C. G., Beem, L. H., Behar, A., Burnett, J., Christner, B. C., Fisher, A. T., Fricker, H. A., Mankoff, K. D., Powell, R. D., Rack, F., Sampson, D., Scherer, R. P., & Schwartz, S. Y. (2014). WISSARD at Subglacial Lake Whillans, West Antarctica: Scientific operations and initial observations. In Annals of Glaciology (65 ed., Vol. 55, pp. 51-58). International Glaciology Society. https://doi.org/10.3189/2014AoG65A009

Tulaczyk, S, Mikucki, JA, Siegfried, MR, Priscu, JC, Barcheck, CG, Beem, LH, Behar, A, Burnett, J, Christner, BC, Fisher, AT, Fricker, HA, Mankoff, KD, Powell, RD, Rack, F, Sampson, D, Scherer, RP & Schwartz, SY 2014, WISSARD at Subglacial Lake Whillans, West Antarctica: Scientific operations and initial observations. in Annals of Glaciology. 65 edn, vol. 55, International Glaciology Society, pp. 51-58. https://doi.org/10.3189/2014AoG65A009

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title = "WISSARD at Subglacial Lake Whillans, West Antarctica: Scientific operations and initial observations",

abstract = "A clean hot-water drill was used to gain access to Subglacial Lake Whillans (SLW) in late January 2013 as part of theWhillans Ice Stream Subglacial Access Research Drilling (WISSARD) project. Over 3 days, we deployed an array of scientific tools through the SLW borehole: a downhole camera, a conductivity-temperature-depth (CTD) probe, a Niskin water sampler, an in situ filtration unit, three different sediment corers, a geothermal probe and a geophysical sensor string. Our observations confirm the existence of a subglacial water reservoir whose presence was previously inferred from satellite altimetry and surface geophysics. Subglacial water is about two orders of magnitude less saline than sea water (0.37-0.41 psu vs 35 psu) and two orders of magnitude more saline than pure drill meltwater (0.002 psu). It reaches a minimum temperature of -0.558C, consistent with depression of the freezing point by 7.019MPa of water pressure. Subglacial water was turbid and remained turbid following filtration through 0.45 mm filters. The recovered sediment cores, which sampled down to 0.8m below the lake bottom, contained a macroscopically structureless diamicton with shear strength between 2 and 6 kPa. Our main operational recommendation for future subglacial access through water-filled boreholes is to supply enough heat to the top of the borehole to keep it from freezing.",

keywords = "Antarctic glaciology, Ice streams, Subglacial lakes, Subglacial processes, Subglacial sediments",

author = "Slawek Tulaczyk and Mikucki, {Jill A.} and Siegfried, {Matthew R.} and Priscu, {John C.} and Barcheck, {C. Grace} and Beem, {Lucas H.} and Alberto Behar and Justin Burnett and Christner, {Brent C.} and Fisher, {Andrew T.} and Fricker, {Helen A.} and Mankoff, {Kenneth D.} and Powell, {Ross D.} and Frank Rack and Daniel Sampson and Scherer, {Reed P.} and Schwartz, {Susan Y.}",

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T2 - Scientific operations and initial observations

AU - Tulaczyk, Slawek

AU - Mikucki, Jill A.

AU - Siegfried, Matthew R.

AU - Priscu, John C.

AU - Barcheck, C. Grace

AU - Beem, Lucas H.

AU - Behar, Alberto

AU - Burnett, Justin

AU - Christner, Brent C.

AU - Fisher, Andrew T.

AU - Fricker, Helen A.

AU - Mankoff, Kenneth D.

AU - Powell, Ross D.

AU - Rack, Frank

AU - Sampson, Daniel

AU - Scherer, Reed P.

AU - Schwartz, Susan Y.

PY - 2014/9/1

Y1 - 2014/9/1

N2 - A clean hot-water drill was used to gain access to Subglacial Lake Whillans (SLW) in late January 2013 as part of theWhillans Ice Stream Subglacial Access Research Drilling (WISSARD) project. Over 3 days, we deployed an array of scientific tools through the SLW borehole: a downhole camera, a conductivity-temperature-depth (CTD) probe, a Niskin water sampler, an in situ filtration unit, three different sediment corers, a geothermal probe and a geophysical sensor string. Our observations confirm the existence of a subglacial water reservoir whose presence was previously inferred from satellite altimetry and surface geophysics. Subglacial water is about two orders of magnitude less saline than sea water (0.37-0.41 psu vs 35 psu) and two orders of magnitude more saline than pure drill meltwater (0.002 psu). It reaches a minimum temperature of -0.558C, consistent with depression of the freezing point by 7.019MPa of water pressure. Subglacial water was turbid and remained turbid following filtration through 0.45 mm filters. The recovered sediment cores, which sampled down to 0.8m below the lake bottom, contained a macroscopically structureless diamicton with shear strength between 2 and 6 kPa. Our main operational recommendation for future subglacial access through water-filled boreholes is to supply enough heat to the top of the borehole to keep it from freezing.

AB - A clean hot-water drill was used to gain access to Subglacial Lake Whillans (SLW) in late January 2013 as part of theWhillans Ice Stream Subglacial Access Research Drilling (WISSARD) project. Over 3 days, we deployed an array of scientific tools through the SLW borehole: a downhole camera, a conductivity-temperature-depth (CTD) probe, a Niskin water sampler, an in situ filtration unit, three different sediment corers, a geothermal probe and a geophysical sensor string. Our observations confirm the existence of a subglacial water reservoir whose presence was previously inferred from satellite altimetry and surface geophysics. Subglacial water is about two orders of magnitude less saline than sea water (0.37-0.41 psu vs 35 psu) and two orders of magnitude more saline than pure drill meltwater (0.002 psu). It reaches a minimum temperature of -0.558C, consistent with depression of the freezing point by 7.019MPa of water pressure. Subglacial water was turbid and remained turbid following filtration through 0.45 mm filters. The recovered sediment cores, which sampled down to 0.8m below the lake bottom, contained a macroscopically structureless diamicton with shear strength between 2 and 6 kPa. Our main operational recommendation for future subglacial access through water-filled boreholes is to supply enough heat to the top of the borehole to keep it from freezing.

KW - Antarctic glaciology

KW - Ice streams

KW - Subglacial lakes

KW - Subglacial processes

KW - Subglacial sediments

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DO - 10.3189/2014AoG65A009

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VL - 55

SP - 51

EP - 58

BT - Annals of Glaciology

PB - International Glaciology Society

ER -

WISSARD at Subglacial Lake Whillans, West Antarctica: Scientific operations and initial observations

Abstract

Keywords

ASJC Scopus subject areas

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