GPS-derived estimates of surface mass balance and ocean-induced basal melt for Pine Island Glacier ice shelf, Antarctica

GPS-derived estimates of surface mass balance and ocean-induced basal melt for Pine Island Glacier ice shelf, Antarctica

In the last 2 decades, Pine Island Glacier (PIG) experienced marked speedup, thinning, and grounding-line retreat, likely due to marine ice-sheet instability and ice-shelf basal melt. To better understand these processes, we combined 2008–2010 and 2012–2014 GPS records with dynamic firn model ou...

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Main Authors: D. E. Shean, K. Christianson, K. M. Larson, S. R. M. Ligtenberg, I. R. Joughin, B. E. Smith, C. M. Stevens, M. Bushuk, D. M. Holland
Format: Article
Language:English
Published: Copernicus Publications 2017-11-01
Series:The Cryosphere
Online Access:https://www.the-cryosphere.net/11/2655/2017/tc-11-2655-2017.pdf
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spelling doaj-798cfbee8ed9445dbeffd445c4dfc1ac2020-11-24T21:03:05ZengCopernicus PublicationsThe Cryosphere1994-04161994-04242017-11-01112655267410.5194/tc-11-2655-2017GPS-derived estimates of surface mass balance and ocean-induced basal melt for Pine Island Glacier ice shelf, AntarcticaD. E. Shean0D. E. Shean1K. Christianson2K. M. Larson3S. R. M. Ligtenberg4I. R. Joughin5B. E. Smith6C. M. Stevens7M. Bushuk8D. M. Holland9D. M. Holland10Applied Physics Laboratory Polar Science Center, University of Washington, Seattle, WA, USADepartment of Civil and Environmental Engineering, University of Washington, Seattle, WA, USADepartment of Earth and Space Sciences, University of Washington, Seattle, WA, USADepartment of Aerospace Engineering Sciences, University of Colorado, Boulder, CO, USAInstitute for Marine and Atmospheric research Utrecht, Utrecht University, Utrecht, the NetherlandsApplied Physics Laboratory Polar Science Center, University of Washington, Seattle, WA, USAApplied Physics Laboratory Polar Science Center, University of Washington, Seattle, WA, USADepartment of Earth and Space Sciences, University of Washington, Seattle, WA, USAGeophysical Fluid Dynamics Laboratory, Princeton University, Princeton, NJ, USACourant Institute of Mathematical Sciences, New York University, New York, NY, USACenter for Global Sea-Level Change, New York University, Abu Dhabi, United Arab EmiratesIn the last 2 decades, Pine Island Glacier (PIG) experienced marked speedup, thinning, and grounding-line retreat, likely due to marine ice-sheet instability and ice-shelf basal melt. To better understand these processes, we combined 2008–2010 and 2012–2014 GPS records with dynamic firn model output to constrain local surface and basal mass balance for PIG. We used GPS interferometric reflectometry to precisely measure absolute surface elevation (<i>z</i><sub>surf</sub>) and Lagrangian surface elevation change (D<i>z</i><sub>surf</sub>∕ D<i>t</i>). Observed surface elevation relative to a firn layer tracer for the initial surface (<i>z</i><sub>surf</sub> − <i>z</i><sub>surf0′</sub>) is consistent with model estimates of surface mass balance (SMB, primarily snow accumulation). A relatively abrupt  ∼  0.2–0.3 m surface elevation decrease, likely due to surface melt and increased compaction rates, is observed during a period of warm atmospheric temperatures from December 2012 to January 2013. Observed D<i>z</i><sub>surf</sub>∕ D<i>t</i> trends (−1 to −4 m yr<sup>−1</sup>) for the PIG shelf sites are all highly linear. Corresponding basal melt rate estimates range from  ∼  10 to 40 m yr<sup>−1</sup>, in good agreement with those derived from ice-bottom acoustic ranging, phase-sensitive ice-penetrating radar, and high-resolution stereo digital elevation model (DEM) records. The GPS and DEM records document higher melt rates within and near features associated with longitudinal extension (i.e., transverse surface depressions, rifts). Basal melt rates for the 2012–2014 period show limited temporal variability despite large changes in ocean temperature recorded by moorings in Pine Island Bay. Our results demonstrate the value of long-term GPS records for ice-shelf mass balance studies, with implications for the sensitivity of ice–ocean interaction at PIG.https://www.the-cryosphere.net/11/2655/2017/tc-11-2655-2017.pdf
collection DOAJ
language English
format Article
sources DOAJ
author D. E. Shean
D. E. Shean
K. Christianson
K. M. Larson
S. R. M. Ligtenberg
I. R. Joughin
B. E. Smith
C. M. Stevens
M. Bushuk
D. M. Holland
D. M. Holland
spellingShingle D. E. Shean
D. E. Shean
K. Christianson
K. M. Larson
S. R. M. Ligtenberg
I. R. Joughin
B. E. Smith
C. M. Stevens
M. Bushuk
D. M. Holland
D. M. Holland
GPS-derived estimates of surface mass balance and ocean-induced basal melt for Pine Island Glacier ice shelf, Antarctica
The Cryosphere
author_facet D. E. Shean
D. E. Shean
K. Christianson
K. M. Larson
S. R. M. Ligtenberg
I. R. Joughin
B. E. Smith
C. M. Stevens
M. Bushuk
D. M. Holland
D. M. Holland
author_sort D. E. Shean
title GPS-derived estimates of surface mass balance and ocean-induced basal melt for Pine Island Glacier ice shelf, Antarctica
title_short GPS-derived estimates of surface mass balance and ocean-induced basal melt for Pine Island Glacier ice shelf, Antarctica
title_full GPS-derived estimates of surface mass balance and ocean-induced basal melt for Pine Island Glacier ice shelf, Antarctica
title_fullStr GPS-derived estimates of surface mass balance and ocean-induced basal melt for Pine Island Glacier ice shelf, Antarctica
title_full_unstemmed GPS-derived estimates of surface mass balance and ocean-induced basal melt for Pine Island Glacier ice shelf, Antarctica
title_sort gps-derived estimates of surface mass balance and ocean-induced basal melt for pine island glacier ice shelf, antarctica
publisher Copernicus Publications
series The Cryosphere
issn 1994-0416
1994-0424
publishDate 2017-11-01
description In the last 2 decades, Pine Island Glacier (PIG) experienced marked speedup, thinning, and grounding-line retreat, likely due to marine ice-sheet instability and ice-shelf basal melt. To better understand these processes, we combined 2008–2010 and 2012–2014 GPS records with dynamic firn model output to constrain local surface and basal mass balance for PIG. We used GPS interferometric reflectometry to precisely measure absolute surface elevation (<i>z</i><sub>surf</sub>) and Lagrangian surface elevation change (D<i>z</i><sub>surf</sub>∕ D<i>t</i>). Observed surface elevation relative to a firn layer tracer for the initial surface (<i>z</i><sub>surf</sub> − <i>z</i><sub>surf0′</sub>) is consistent with model estimates of surface mass balance (SMB, primarily snow accumulation). A relatively abrupt  ∼  0.2–0.3 m surface elevation decrease, likely due to surface melt and increased compaction rates, is observed during a period of warm atmospheric temperatures from December 2012 to January 2013. Observed D<i>z</i><sub>surf</sub>∕ D<i>t</i> trends (−1 to −4 m yr<sup>−1</sup>) for the PIG shelf sites are all highly linear. Corresponding basal melt rate estimates range from  ∼  10 to 40 m yr<sup>−1</sup>, in good agreement with those derived from ice-bottom acoustic ranging, phase-sensitive ice-penetrating radar, and high-resolution stereo digital elevation model (DEM) records. The GPS and DEM records document higher melt rates within and near features associated with longitudinal extension (i.e., transverse surface depressions, rifts). Basal melt rates for the 2012–2014 period show limited temporal variability despite large changes in ocean temperature recorded by moorings in Pine Island Bay. Our results demonstrate the value of long-term GPS records for ice-shelf mass balance studies, with implications for the sensitivity of ice–ocean interaction at PIG.
url https://www.the-cryosphere.net/11/2655/2017/tc-11-2655-2017.pdf
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