Ice and firn heterogeneity within Larsen C Ice Shelf from borehole optical televiewing

David W. Ashmore; Bryn Hubbard; Adrian Luckman; Bernd Kulessa; Suzanne Bevan; Adam Booth; Peter Kuipers Munneke; Martin O'Leary; Heidi Sevestre; Paul R. Holland

doi:10.1002/2016JF004047

Ice and firn heterogeneity within Larsen C Ice Shelf from borehole optical televiewing

David W. Ashmore, Bryn Hubbard, Adrian Luckman, Bernd Kulessa, Suzanne Bevan, Adam Booth, Peter Kuipers Munneke, Martin O'Leary, Heidi Sevestre, Paul R. Holland

Research output: Contribution to journal › Article › peer-review

Abstract

We use borehole optical televiewing (OPTV) to explore the internal structure of Larsen C Ice Shelf (LCIS). We report a suite of five ~90 m long OPTV logs, recording a light-emitting diode-illuminated, geometrically correct image of the borehole wall, from the northern and central sectors of LCIS collected during austral spring 2014 and 2015. We use a thresholding-based technique to estimate the refrozen ice content of the ice column and exploit a recently calibrated density-luminosity relationship to reveal its structure. All sites are dense and strongly influenced by surface melt, with frequent refrozen ice layers and mean densities, between the depths of 1.87 and 90 m, ranging from 862 to 894 kg m⁻³. We define four distinct units that comprise LCIS and relate these to ice provenance, dynamic history, and past melt events. These units are in situ meteoric ice with infiltration ice (U1), meteoric ice which has undergone enhanced densification (U2), thick refrozen ice (U3), and advected continental ice (U4). We show that the OPTV-derived pattern of firn air content is consistent with previous estimates, but that a significant proportion of firn air is contained within U4, which we interpret to have been deposited inland of the grounding line. The structure of LCIS is strongly influenced by the E-W gradient in föhn-driven melting, with sites close to the Antarctic Peninsula being predominantly composed of refrozen ice. Melting is also substantial toward the ice shelf center with >40% of the overall imaged ice column being composed of refrozen ice.

Original language	English
Pages (from-to)	1139-1153
Number of pages	15
Journal	Journal of Geophysical Research - Earth Surface
Volume	122
Issue number	5
Early online date	20 May 2017
DOIs	https://doi.org/10.1002/2016JF004047
Publication status	Published - May 2017

Keywords

Ice shelves
Glaciology
Antarctica

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10.1002/2016JF004047Licence: CC BY

Sevestre_2017_JGRES_LarsenCIceShelf_CC
© 2017 The Authors. This is an open access article under the terms of the Creative Commons Attribution License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited.
Final published version, 7.31 MBLicence: CC BY

Cite this

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title = "Ice and firn heterogeneity within Larsen C Ice Shelf from borehole optical televiewing",

abstract = "We use borehole optical televiewing (OPTV) to explore the internal structure of Larsen C Ice Shelf (LCIS). We report a suite of five ~90 m long OPTV logs, recording a light-emitting diode-illuminated, geometrically correct image of the borehole wall, from the northern and central sectors of LCIS collected during austral spring 2014 and 2015. We use a thresholding-based technique to estimate the refrozen ice content of the ice column and exploit a recently calibrated density-luminosity relationship to reveal its structure. All sites are dense and strongly influenced by surface melt, with frequent refrozen ice layers and mean densities, between the depths of 1.87 and 90 m, ranging from 862 to 894 kg m−3. We define four distinct units that comprise LCIS and relate these to ice provenance, dynamic history, and past melt events. These units are in situ meteoric ice with infiltration ice (U1), meteoric ice which has undergone enhanced densification (U2), thick refrozen ice (U3), and advected continental ice (U4). We show that the OPTV-derived pattern of firn air content is consistent with previous estimates, but that a significant proportion of firn air is contained within U4, which we interpret to have been deposited inland of the grounding line. The structure of LCIS is strongly influenced by the E-W gradient in f{\"o}hn-driven melting, with sites close to the Antarctic Peninsula being predominantly composed of refrozen ice. Melting is also substantial toward the ice shelf center with >40% of the overall imaged ice column being composed of refrozen ice.",

keywords = "Ice shelves, Glaciology, Antarctica",

author = "Ashmore, {David W.} and Bryn Hubbard and Adrian Luckman and Bernd Kulessa and Suzanne Bevan and Adam Booth and Munneke, {Peter Kuipers} and Martin O'Leary and Heidi Sevestre and Holland, {Paul R.}",

note = "Research was funded by the UK Natural Environmental Research Council grants NE/L006707/1 and NE/L005409/1 and a HEFCW/Aberystwyth University Capital Equipment Grant to B.H. Data will be available via the project website (www.projectmidas.org) and the UK Polar Data Centre (https://www.bas.ac.uk/data/uk-pdc/) from mid-2017.",

year = "2017",

month = may,

doi = "10.1002/2016JF004047",

language = "English",

volume = "122",

pages = "1139--1153",

journal = "Journal of Geophysical Research - Earth Surface",

issn = "2169-9011",

publisher = "John Wiley & Sons, Ltd",

number = "5",

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TY - JOUR

T1 - Ice and firn heterogeneity within Larsen C Ice Shelf from borehole optical televiewing

AU - Ashmore, David W.

AU - Hubbard, Bryn

AU - Luckman, Adrian

AU - Kulessa, Bernd

AU - Bevan, Suzanne

AU - Booth, Adam

AU - Munneke, Peter Kuipers

AU - O'Leary, Martin

AU - Sevestre, Heidi

AU - Holland, Paul R.

N1 - Research was funded by the UK Natural Environmental Research Council grants NE/L006707/1 and NE/L005409/1 and a HEFCW/Aberystwyth University Capital Equipment Grant to B.H. Data will be available via the project website (www.projectmidas.org) and the UK Polar Data Centre (https://www.bas.ac.uk/data/uk-pdc/) from mid-2017.

PY - 2017/5

Y1 - 2017/5

N2 - We use borehole optical televiewing (OPTV) to explore the internal structure of Larsen C Ice Shelf (LCIS). We report a suite of five ~90 m long OPTV logs, recording a light-emitting diode-illuminated, geometrically correct image of the borehole wall, from the northern and central sectors of LCIS collected during austral spring 2014 and 2015. We use a thresholding-based technique to estimate the refrozen ice content of the ice column and exploit a recently calibrated density-luminosity relationship to reveal its structure. All sites are dense and strongly influenced by surface melt, with frequent refrozen ice layers and mean densities, between the depths of 1.87 and 90 m, ranging from 862 to 894 kg m−3. We define four distinct units that comprise LCIS and relate these to ice provenance, dynamic history, and past melt events. These units are in situ meteoric ice with infiltration ice (U1), meteoric ice which has undergone enhanced densification (U2), thick refrozen ice (U3), and advected continental ice (U4). We show that the OPTV-derived pattern of firn air content is consistent with previous estimates, but that a significant proportion of firn air is contained within U4, which we interpret to have been deposited inland of the grounding line. The structure of LCIS is strongly influenced by the E-W gradient in föhn-driven melting, with sites close to the Antarctic Peninsula being predominantly composed of refrozen ice. Melting is also substantial toward the ice shelf center with >40% of the overall imaged ice column being composed of refrozen ice.

AB - We use borehole optical televiewing (OPTV) to explore the internal structure of Larsen C Ice Shelf (LCIS). We report a suite of five ~90 m long OPTV logs, recording a light-emitting diode-illuminated, geometrically correct image of the borehole wall, from the northern and central sectors of LCIS collected during austral spring 2014 and 2015. We use a thresholding-based technique to estimate the refrozen ice content of the ice column and exploit a recently calibrated density-luminosity relationship to reveal its structure. All sites are dense and strongly influenced by surface melt, with frequent refrozen ice layers and mean densities, between the depths of 1.87 and 90 m, ranging from 862 to 894 kg m−3. We define four distinct units that comprise LCIS and relate these to ice provenance, dynamic history, and past melt events. These units are in situ meteoric ice with infiltration ice (U1), meteoric ice which has undergone enhanced densification (U2), thick refrozen ice (U3), and advected continental ice (U4). We show that the OPTV-derived pattern of firn air content is consistent with previous estimates, but that a significant proportion of firn air is contained within U4, which we interpret to have been deposited inland of the grounding line. The structure of LCIS is strongly influenced by the E-W gradient in föhn-driven melting, with sites close to the Antarctic Peninsula being predominantly composed of refrozen ice. Melting is also substantial toward the ice shelf center with >40% of the overall imaged ice column being composed of refrozen ice.

KW - Ice shelves

KW - Glaciology

KW - Antarctica

U2 - 10.1002/2016JF004047

DO - 10.1002/2016JF004047

M3 - Article

SN - 2169-9011

VL - 122

SP - 1139

EP - 1153

JO - Journal of Geophysical Research - Earth Surface

JF - Journal of Geophysical Research - Earth Surface

IS - 5

ER -

Ice and firn heterogeneity within Larsen C Ice Shelf from borehole optical televiewing

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