Skip to main content
Journal ArticleOPEN ACCESS

Speedup and fracturing of George VI Ice Shelf, Antarctic Peninsula

Cryosphere (2013) 7(3) 797-816
DOI: 10.5194/tc-7-797-2013
34Citations
Citations of this article
88Readers
Mendeley users who have this article in their library.

Abstract

George VI Ice Shelf (GVIIS) is located on the Antarctic Peninsula, a region where several ice shelves have undergone rapid breakup in response to atmospheric and oceanic warming. We use a combination of optical (Landsat), radar (ERS 1/2 SAR) and laser altimetry (GLAS) datasets to examine the response of GVIIS to environmental change and to offer an assessment on its future stability. The spatial and structural changes of GVIIS (ca. 1973 to ca. 2010) are mapped and surface velocities are calculated at different time periods (InSAR and optical feature tracking from 1989 to 2009) to document changes in the ice shelf's flow regime. Surface elevation changes are recorded between 2003 and 2008 using repeat track ICESat acquisitions. We note an increase in fracture extent and distribution at the south ice front, ice-shelf acceleration towards both the north and south ice fronts and spatially varied negative surface elevation change throughout, with greater variations observed towards the central and southern regions of the ice shelf. We propose that whilst GVIIS is in no imminent danger of collapse, it is vulnerable to ongoing atmospheric and oceanic warming and is more susceptible to breakup along its southern margin in ice preconditioned for further retreat. © Author(s) 2013.

Figures

  • Fig. 1. (A) George VI Ice Shelf with localities mentioned in the text and its key tributary glaciers. The names of tributary glaciers were taken from the Antarctic Place-names Committee (http://www.antarctica.ac.uk/apc/) except for those labelled “GT##” that were otherwise previously unnamed. Note the positioning of the −9 °C mean annual isotherm across Alexander Island (source: Morris and Vaughan, 2003). MB = Marguerite Bay. (B) The Antarctic Peninsula region displaying localities mentioned in the text, including the embayments of former ice shelves.
  • Table 1. Ice-shelf features, identifying criteria and significance. Adapted from Glasser and Scambos (2008) and Glasser et al. (2009). See Fig. 2 for full structural map of GVIIS and Figs. 4 and 5 for the north and south ice fronts, respectively.
  • Fig. 2. (A) Glaciological structural overview (2010) illustrating the dominance of longitudinal structures, surface meltwater and rifts towards the south ice front (see Table 1 for a full list of identifying criteria and significance of ice-shelf structures and surface features). Retreat patterns of the northern (Ai, B) and southern (Aii, C) ice fronts are also illustrated: note in particular the large-scale breakup followed by more steady retreat at the north ice front and concentrated retreat in the central section of the south ice front between ca. 1973 and 2010.
  • Table 2. Datasets produced for GVIIS.
  • Fig. 3. Total ice loss (bars) and rate of loss (lines) for GVIIS north and GVIIS south ice fronts between ca. 1973 and 2010. Note the major ice loss event between 1974 and 1979 at the north ice front followed by a period of comparatively steady retreat. Loss at the south ice front is more regular across the observation period, although retreat rate doubles between 1990 and 1995. There is no relationship between ice loss quantity or timing between the north and south ice fronts.
  • Fig. 4. Structural evolution at the north ice front illustrating widespread rifting that encouraged retreat. Note the long-term development of rifts (B) from the eastern grounding line that eventually form the frontal profile during 1979 and 1989. Post 2001 there are few ice-shelf-wide rifts at the northern ice front.
  • Fig. 5. Structural evolution at the south ice front illustrating widespread rifting lee side of the Eklund Islands and the English Coast. Increased rifting is apparent between the Eklund Islands and De Atley Island. During March 2010, a weak ice bridge north of the largest Eklund Island broke apart leaving two independent ice fronts (SIF1 and SIF2).
  • Fig. 6. Surface-speed calculations at the north ice front for ca. 1989 (A), ca. 1995 (B), ca. 2002 (C) and ca. 2007 (D) illustrating an increase in flow speed of glacier ice flowing from Riley Glacier as the ice front retreated upstream. Less active ice is apparent in each observation period that is inferred to be buttressed by the dominant flow from Riley Glacier at the ice front. Black dots represent the centre point of tracked features that were used to interpolate surface speeds. Uncertainties: (A) ± 30 m a−1, (B) ± 25 m a−1, (C) 15 ± m a−1, (D) ± 15 m a−1.

References Powered by Scopus

Antarctic ice-sheet loss driven by basal melting of ice shelves

Nature
1037Citations
N/AReaders
Get full text

Recent rapid regional climate warming on the Antarctic Peninsula

Climatic Change
1032Citations
N/AReaders
Get full text

Acceleration of the contribution of the Greenland and Antarctic ice sheets to sea level rise

Geophysical Research Letters
917Citations
N/AReaders
Get full text
View more at Scopus

Cited by Powered by Scopus

Ocean-driven thinning enhances iceberg calving and retreat of Antarctic ice shelves

Proceedings of the National Academy of Sciences of the United States of America
222Citations
N/AReaders
Get full text

Dynamic thinning of glaciers on the Southern Antarctic Peninsula

Science
177Citations
N/AReaders
Get full text

Surge-type and surge-modified glaciers in the Karakoram

Scientific Reports
167Citations
N/AReaders
Get full text
View more at Scopus

Register to see more suggestions

Mendeley helps you to discover research relevant for your work.

Already have an account?

Cite

CITATION STYLE

APA

Holt, T. O., Glasser, N. F., Quincey, D. J., & Siegfried, M. R. (2013). Speedup and fracturing of George VI Ice Shelf, Antarctic Peninsula. Cryosphere, 7(3), 797–816. https://doi.org/10.5194/tc-7-797-2013

Readers over time

‘13‘14‘15‘16‘17‘18‘19‘20‘21‘22‘23‘24‘2505101520

Readers' Seniority

Tooltip

PhD / Post grad / Masters / Doc 35

58%

Researcher 19

32%

Professor / Associate Prof. 4

7%

Lecturer / Post doc 2

3%

Readers' Discipline

Tooltip

Earth and Planetary Sciences 45

70%

Environmental Science 13

20%

Physics and Astronomy 4

6%

Engineering 2

3%

Save time finding and organizing research with Mendeley

Sign up for free
0