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A structural glaciological analysis of the 2002 Larsen B ice-shelf collapse

Published online by Cambridge University Press:  08 September 2017

N.F. Glasser  and
T.A. Scambos
N.F. Glasser
Affiliation:
Centre for Glaciology, Institute of Geography and Earth Sciences, Aberystwyth University, Aberystwyth SY23 3DB, UK E-mail: nfg@aber.ac.uk
T.A. Scambos
Affiliation:
National Snow and Ice Data Center, CIRES, University of Colorado, Boulder, Colorado 80309-0449, USA
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Abstract

This study provides a detailed structural glaciological analysis of changes in surface structures on the Larsen B ice shelf on the Antarctic Peninsula prior to its collapse in February–March 2002. Mapped features include the ice-shelf front, rifts, crevasses, longitudinal linear surface structures and meltwater features. We define domains on the ice shelf related to glacier source areas and demonstrate that, prior to collapse, the central Larsen B ice shelf consisted of four sutured flow units fed by Crane, Jorum, Punchbowl and Hektoria/Green/Evans glaciers. Between these flow units were ‘suture zones’ of thinner ice where the feeder glaciers merged. Prior to collapse, large open-rift systems were present offshore of Foyn Point and Cape Disappointment. These rifts became more pronounced in the years preceding break-up, and ice blocks in the rifts rotated because of the strong lateral shear in this zone. Velocity mapping of the suture zones indicates that the major rifts were not present more than about 20 years ago. We suggest that the ice shelf was preconditioned to collapse by partial rupturing of the sutures between flow units. This, we believe, was the result of ice-shelf front retreat during 1998–2000, reducing the lateral resistive stress on the upstream parts of the shelf and glacier flow units, ice-shelf thinning and pre-shelf-break-up glacier acceleration.

Type
Research Article
Information
Journal of Glaciology , Volume 54 , Issue 184 , 2008 , pp. 3 - 16
Copyright
Copyright © International Glaciological Society 2008

Introduction

Ice shelves fringe ∼45% of the Antarctic continent. They are important in global Earth-system processes for five main reasons: (1) ice shelves play a significant role in the global ice-volume/sea-level system because the calving of icebergs from their termini accounts for ∼90% of Antarctic ice loss (Reference Vaughan and DoakeVaughan and Doake, 1996; Reference MacAyeal, Scambos, Hulbe and FahnestockMacAyeal and others, 2003); (2) ice shelves influence the dynamics, and therefore the system response time, of upstream inland Antarctic ice (Reference Rott, Rack, Skvarca and De AngelisRott and others, 2002; Reference De Angelis and SkvarcaDe Angelis and Skvarca, 2003; Reference Scambos, Bohlander, Shuman and SkvarcaScambos and others, 2004); (3) rapid heat exchange in sub-ice-shelf cavities has a significant impact on the global ocean heat budget (Reference Williams, Grosfeld, Warner, Gerdes and DetermannWilliams and others, 2001; Reference Joughin and PadmanJoughin and Padman, 2003); (4) ice shelves are capable of entraining, transporting and depositing large quantities of glacigenic material (Reference Evans and PudseyEvans and Pudsey, 2002; Reference Evans and CofaighEvans and Ó Cofaigh, 2003; Reference Glasser, Goodsell, Copland and LawsonGlasser and others, 2006); and (5) catastrophic iceberg-calving events from ice shelves have been proposed as a cause of major Late Quaternary climatic perturbations (Reference Hulbe, MacAyeal, Denton, Kleman and LowellHulbe and others, 2004).

Ice-shelf collapse and regrowth has occurred in the recent geological past. The sedimentary record on the continental shelf indicates that some Antarctic Peninsula ice shelves (e.g. the Prince Gustav Channel Ice Shelf (Reference Pudsey and EvansPudsey and Evans, 2001) and the George VI Ice Shelf (Reference Hjort, Bentley and IngólfssonHjort and others, 2001)) retreated in the mid-Holocene and may follow an asymmetrical cyclic process, involving rapid disintegration followed by gradual expansion. However, the collapse of the Larsen B ice shelf is apparently unprecedented in the Holocene (Reference DomackDomack and others, 2005). Recent mass loss from the northern Antarctic Peninsula is estimated to be sufficient to raise eustatic sea level by between 0.1 (Reference RignotRignot and others, 2005) and 0.16 ± 0.06 mm a−1 (Reference Pritchard and VaughanPritchard and Vaughan, 2007).

Most of the ice shelves that have retreated on the Antarctic Peninsula have shown two phases of retreat: a climatically driven progressive retreat that occurred for years (and in some cases decades) and a more rapid collapse phase (Doake and others, 1998; Reference MacAyeal, Scambos, Hulbe and FahnestockMacAyeal and others, 2003; Reference Morris, Vaughan, Domack, Leventer, Burnett, Bindschadler, Convey and KirbyMorris and Vaughan, 2003; Reference Scambos, Hulbe, Fahnestock, Domack, Burnett, Leventer, Conley, Kirby and BindschadlerScambos and others, 2003; Reference Vieli, Payne, Du and ShepherdVieli and others, 2006, Reference Vieli, Payne, Shepherd and Du2007). There are indications that, in some cases, ice-shelf collapse events are a direct result of recent atmospheric or oceanic warming (Reference Rott, Rack, Nagler and SkvarcaRott and others, 1998; Reference Scambos, Hulbe, Fahnestock and BohlanderScambos and others, 2000; Reference Shepherd, Wingham, Payne and SkvarcaShepherd and others, 2003). The limit for ice-shelf viability coincides with the −1.5°C January isotherm and the −5°C mean annual isotherm, both of which have moved further south during the last 50 years (Reference Rott, Skvarca and NaglerRott and others, 1996, Reference Rott, Rack, Nagler and Skvarca1998; Reference Vaughan and DoakeVaughan and Doake, 1996; Reference Morris, Vaughan, Domack, Leventer, Burnett, Bindschadler, Convey and KirbyMorris and Vaughan, 2003). Because mean summer temperatures have risen to near-melting and the length of the melt season has doubled during the last two decades, meltwater ponds have appeared on the surface of many Antarctic Peninsula ice shelves during the melt season (Reference Van den BroekeVan den Broeke, 2005). It has been suggested that this meltwater acts as a mechanical force in the crevasses, causing breaks in the ice shelf and thus accelerating ice-shelf disintegration (Reference MacAyeal, Scambos, Hulbe and FahnestockMacAyeal and others, 2003; Reference Scambos, Hulbe, Fahnestock, Domack, Burnett, Leventer, Conley, Kirby and BindschadlerScambos and others, 2003; Reference Van der VeenVan der Veen, 2007).

Here we present the results of detailed structural mapping of the Larsen B ice shelf and its tributary glaciers in the period just preceding and immediately after the 2002 ice-shelf collapse. The Larsen Ice Shelf was first given the sub-names Larsen ice shelf A, B, C and D by Reference Vaughan and DoakeVaughan and Doake (1996) (Fig. 1). Of these ice shelves only the southwest corner of the Larsen B, and the Larsen C and D remain. Larsen A ice shelf collapsed in January 1995 with the loss of 1600 km2 of ice shelf (Reference Rott, Skvarca and NaglerRott and others, 1996). Larsen B partially collapsed in February–March 2002 with the loss of 3200 km2 of ice shelf (Reference Scambos, Hulbe, Fahnestock, Domack, Burnett, Leventer, Conley, Kirby and BindschadlerScambos and others, 2003; Reference Rack and RottRack and Rott, 2004). There are existing descriptions of the surface features of Antarctic ice shelves (e.g. Reference Crabtree and DoakeCrabtree and Doake, 1980; Reference Reynolds and HambreyReynolds and Hambrey, 1988; Reference Swithinbank, Brunk and SieversSwithinbank and others, 1988; Reference Casassa and BrecherCasassa and Brecher, 1993; Reference Hambrey and DowdeswellHambrey and Dowdeswell, 1994; Reference SkvarcaSkvarca, 1994; Reference Bindschadler, Scambos, Rott, Skvarca and VornbergerBindschadler and others, 2002; Reference Evans and CofaighEvans and Ó Cofaigh, 2003), but very little is known about the temporal changes in these surface features and the role that they play in ice-shelf break-up.

Fig. 1. Portion of the 1997 RAMP (RADARSAT-1 Antarctic Mapping Project) mosaic showing the Antarctic Peninsula and place names mentioned in the text. The location of the mapped area shown in Figure 2 is indicated.

Methods

Surface structures in the Larsen B ice shelf area and its tributary glaciers were mapped from satellite imagery in ArcMap GIS (Geographical Information System) software using time-separated images. We undertook detailed studies of the ice shelf using Landsat 7 ETM+ (Enhanced Thematic Mapper Plus) and ASTER (Advanced Spaceborne Thermal Emission and Reflection Radiometer) scenes obtained before, during and after ice-shelf collapse. Image acquisition dates used in this study are: three ASTER granules acquired on 22 November 2001, and Landsat 7 scenes acquired on 27 January 2000, 21 February 2000, 6 December 2001 and 6 April 2002 (Table 1). Features mapped include the location of the ice-shelf front, the location of rifts (fractures that penetrate the entire ice-shelf thickness), longitudinal surface structures (also known as flow stripes or streak lines), individual flow units, medial moraines and other areas of surface debris, open crevasses and surface meltwater features (streams, ponds, meltwater-filled crevasses and dolines). A complete list of mapped features, with their identification criteria and significance, is provided in Table 2. Satellite image interpretation was performed using multiple band combinations and standard image enhancement procedures (contrast stretching and histogram equalization) to improve the contrast across features. The horizontal resolution of the satellite images (15 m for both the Landsat 7 ETM+ band 8 images and the ASTER band 3 N images) is a limitation on the minimum size of the features mapped. Detailed mapping was carried out by hand-digitizing features in ArcMap at 1 : 50 000 scale.

Table 1. Details of satellite images used in this study

Table 2. Features mapped on the satellite images, together with their identification criteria and possible significance

Results

The results of the mapping are presented below in five parts. We consider (1) ice-shelf tributary-glacier domains on the surface of the ice shelf, (2) meltwater-pond and drainage patterns on the shelf, (3) large-scale changes in the Larsen B ice shelf between January 2000 and April 2002, (4) changes in the tributary-glacier rift systems between February 2000 and April 2002 and (5) changes in ice-shelf tributary glaciers between February 2000 and April 2002. Interpretations of the glaciological significance of the mapped features are presented separately.

Ice-shelf tributary-glacier domains

In the November 2001 ASTER satellite images, the Larsen B ice shelf is composed of at least 14 individual glacier domains (marked as domains 3–16 in Fig. 2). Domains 1 and 2 contribute ice to the former Larsen A ice shelf and domains 3 and 4 contribute little ice volume to the Larsen B ice shelf so are not discussed in detail here. By far the largest contribution to the disintegrated portion of the former Larsen B ice shelf comes from four tributary glaciers: the Hektoria/Green/Evans glacier system (domain 5 in Fig. 2), Punchbowl Glacier (domain 7 in Fig. 2), Jorum Glacier (domain 8 in Fig. 2) and Crane Glacier (domain 10 in Fig. 2). These glaciers feed the ice shelf from narrow glacial valleys, and the glacier ice spreads laterally just downstream of their grounding lines. Splaying crevasse patterns and transverse separation of longitudinal surface structures mark this zone (Fig. 2).

Fig. 2. Tributary-glacier domains on the former Larsen B ice shelf inferred from crevasse patterns and longitudinal surface structures on ASTER mosaic in November 2001. Numbers refer to domains discussed in the text.

Longitudinal surface structures originating in the trunks of these glaciers can be traced uninterrupted all the way to the ice-shelf front. Four smaller tributary glaciers (domains 11–13 and 15) also flow towards the ice shelf but do not contribute significantly to its downstream surface area (Fig. 2). These glaciers are separated from the ice shelf by a large rift originating at the southern end of the grounding line for Crane Glacier and extending out to and past Cape Disappointment. Between domains 5 and 7, 8 and 10, and 10 and 16 are domains lacking significant up-glacier catchments and without longitudinal surface structures (domain 6 originating from Foyn Point, domain 9 originating from Caution Point and domain 14 originating from Cape Disappointment; Fig. 2). Large rift systems are also present on the ice-shelf surface at Foyn Point and Cape Disappointment.

Individual glacier domains on the ice shelf possess very different surface characteristics. The Hektoria/Green/Evans domain (domain 5 in Fig. 2) has both surface meltwater ponds and streams (Fig. 3a), whilst the Crane domain (domain 10 in Fig. 2) has a much rougher, ‘pockmarked’ surface texture consisting of elongate depressions (some of which are meltwater-filled lakes in summer) separated by ridges.

Fig. 3. Sequence illustrating the changes in surface structures on the Larsen B ice shelf between January 2000 and April 2002. (a) Structural interpretation from January 2000. (b) Structural interpretation from February 2000. Numbers 1–9 refer to features on the surface of the ice shelf discussed in the text. Boxes indicate the locations of other figures. (c) Structural interpretation from November 2001. (d) Structural interpretation from April 2002. Note that there is little change in the position of the ice-shelf edge between February 2000 and November 2001 but that the number of rifts and crevasses near the ice-shelf edge has increased by November 2001. By April 2002 the ice shelf has completely disappeared. Numbers refer to localities discussed in the text.

Meltwater-pond and drainage patterns on the shelf

By the austral summer of 2000, the northern and central parts of the Larsen B ice shelf had developed an extensive pattern of meltwater ponds and drainage systems. This was the culmination of a steady increase in the extent of meltwater features and the frequency of warm summers that led to extensive surface melt (Reference MacAyeal, Scambos, Hulbe and FahnestockMacAyeal and others, 2003; Scambos and others, 2003; Reference Van den BroekeVan den Broeke, 2005).

Surface meltwater features dominate the surface of Larsen B ice shelf in both January 2000 (Fig. 3a) and February 2000 (Fig. 3b). Three zones (labelled 1–3 in Fig. 3b) can be clearly distinguished: (1) a zone dominated by linear meltwater features on the northern part of the ice shelf, sometimes forming sinuous drainage networks; (2) a complex system of meltwater features in the area of the ice shelf dominated by the inflow of the Hektoria/Green/Evans glacier system, Jorum Glacier and Crane Glacier where meltwater ponds and streams appear to follow the local topographic slope on the ice-shelf surface (upper part of the image) and fill depressions on its surface along longitudinal surface structures (centre of the image); and (3) an area almost devoid of surface meltwater features on the southern part of the ice shelf.

In areas of the ice shelf where there is little glacier inflow (e.g. Foyn Point and Cape Disappointment domains; Fig. 2) networks of interconnected meltwater streams dominate the surface drainage patterns. The drainage patterns of the streams suggest that the large glacier flanks (e.g. the north side of Crane outflow) and interglacier regions are lower in elevation than the central glacier outflow regions. Indeed, in the area of domains 1–3 (Fig. 2), where there are no longitudinal surface structures to indicate significant glacier inflow, networks of meltwater streams flow towards the ice-shelf front (Fig. 3a). Elevation maps of the ice-shelf surface from radar altimetry (Doake and others, 1998) concur with the suggestion of thinner shelf ice in the suture regions.

In February 2000 an extensive network of meltwater ponds and streams is visible on the ice-shelf surface (Fig. 4a and b). A drained meltwater pond (doline) is visible on the lower left of the image (labelled 1 in Fig. 4a; see also Reference Bindschadler, Scambos, Rott, Skvarca and VornbergerBindschadler and others, 2002). Meltwater ponds and streams appear to follow the local topographic slope on the ice-shelf surface (upper part of image), but they also fill depressions on its surface along longitudinal surface structures (centre of image).

Fig. 4. Changes near the edge of the Larsen B ice shelf between February 2000 and November 2001. (a) Detail of Landsat image acquired in February 2000. Arrow 1 indicates doline; arrow 2 indicates rifts cutting through meltwater streams. (b) Interpretation of the same area. Note that close to the ice-shelf edge the crevasses and rifts are sub-parallel to the ice-shelf edge and cross-cut the meltwater streams and ponds. (c) Detail of ASTER image acquired in November 2001. (d) Interpretation of the same area. Note that there are more rifts close to the ice-shelf edge than in the comparable scene from February 2000.

Meltwater-pond growth on the ice-shelf surface was rapid in the 25 day interval between the acquisitions of the two images. On 27 January 2000 there were 1381 individual meltwater ponds with a total surface area of 251 km2 on the ice-shelf surface. By 21 February 2000 there were 2696 individual meltwater ponds with a total surface area of 365 km2. In both cases, the majority of ponds were small (mean meltwater-pond area of 0.18 km2 in January 2000 and 0.13 km2 in February 2000). Large rifts were visible near the ice-shelf front (labelled 4 and 5 in Fig. 3b) as well as in the ice-shelf interior (labelled 6 in Fig. 3b). Rift systems in the ice shelf in the zones where the Hektoria/Green/Evans glacier system, Jorum Glacier and Crane Glacier (labelled 7, 8 and 9 in Fig. 3b) enter the ice shelf are described in more detail below. Longitudinal surface structures originating in the Hektoria/Green/Evans glacier system, Jorum Glacier and Crane Glacier catchments can be traced across the ice shelf as far as its front.

Large-scale changes in the Larsen B ice shelf between January 2000 and April 2002

A comparison of satellite images from January 2000 (Fig. 3a) and February 2000 (Fig. 3b) with the November 2001 (Fig. 3c) and April 2002 (Fig. 3d) images provides a detailed record of large-scale changes in ice-shelf fracturing, and therefore the stress regime, leading up to its collapse.

Close to the ice-shelf front, crevasses and rifts are developed sub-parallel to the ice-shelf front. The crevasses and rifts cut through (cross-cut) the meltwater streams and ponds (labelled 2 in Fig. 4a). The number and length of rifts close to the ice-shelf front increased between February 2000 and November 2001 (Fig. 4c and d).

Changes in the tributary-glacier rift systems between February 2000 and April 2002

At several points along the grounding line of the ice shelf, major glacier domains are merged to form the ice shelf. However, these regions, typically near capes of rock on the coastline, are marked by major rifting, forming upstream of the capes on either side, and with rifts and melange (areas that consists of a mixture of dissimilar materials) downstream of the merge region of the glacier domains. Open water containing calved icebergs and brash ice is visible within the rifts (e.g. at points labelled 1 and 2 in Fig. 5a). These rift systems are present in all pre-ice-shelf collapse images of the Larsen B ice shelf (e.g. in February 2000 (Fig. 5a) and November 2001 (Fig. 5b)), and after ice-shelf collapse in April 2002 (Fig. 5c).

Fig. 5. (a, b) Detail of the southern part of Larsen B ice shelf prior to ice-shelf collapse in February 2000 (a) and November 2001 (b). (c) The situation after ice-shelf collapse in April 2002. Note that large rift systems containing open water and calved icebergs, labelled 1 and 2 in (a), existed prior to ice-shelf collapse. Note also the rotation of the blocks within the rifts around area 2 between February 2000 and November 2001. The rifts later formed the inward limit of ice-shelf collapse (c).

There were large tributary-glacier rift systems as far as ∼40 km from the pre-collapse ice-shelf front. Rifts form in the less-active zones between active coalescing tributary glaciers (Fig. 3a–d). The largest rift systems are those at Foyn Point and Cape Disappointment (Fig. 5). Rift enlargement and the growth of new rifts is apparent in the interval between the January and February 2000 images and the November and December 2001 scenes. Mapping of the rifted ‘blocks’ shows that these blocks rotated significantly in the intervening time, by up to 45°, indicating non-steady behaviour and increased ice-shelf shearing in this region (Fig. 5a and b). Moreover, examination of the areas downstream of the suture regions indicates there are no downstream ‘rift shadows’. This indicates that the rift patterns at Foyn Point and Cape Disappointment are relatively new features of the ice shelf and did not form, or at least formed much less frequently, in the past. Reference Skvarca, Rack and RottSkvarca and others (1999) show a Landsat Thematic Mapper (TM) image from 1 March 1986, with just three rifts in the vicinity of Cape Disappointment, and none of the rifted melange we have mapped north of the cape was present at that time. Similarly, far less rifting is visible near Foyn Point in the 1986 Landsat TM image.

Image-to-image cross-correlation techniques (Reference Scambos, Dutkiewicz, Wilson and BindschadlerScambos and others, 1992) were used to make ice-velocity measurements in the Foyn Point and Cape Disappointment regions (Fig. 6). In the Foyn Point region these measurements indicate ice-flow speeds of 460–525 m a−1 in the regions downstream of Foyn Point in the early 2000 to late 2001 interval (using the 21 February 2000 and 22 November 2001 image pair, a separation of 1.75 years). Rifts in this region decreased in extent and increased in spacing downstream of Foyn Point and are no longer discernible beyond ∼10 km from Foyn Point. This suggests that the large rifts, and the separation of the shelf ice from the cape, began ∼20–25 years ago. Similarly, at Cape Disappointment, measurements indicate large variations in ice-flow speeds between the ice shelf in the Cape Disappointment region and downstream of the Cape.

Fig. 6. Ice-velocity measurements in the Foyn Point and Cape Disappointment regions between 21 February 2000 and 22 November 2001 using image-to-image cross-correlation techniques (Reference Scambos, Dutkiewicz, Wilson and BindschadlerScambos and others, 1992). Dots indicate ice-motion measurement vector midpoints from which the velocity fields were interpolated.

In the post-ice-shelf-collapse image acquired in April 2002 (Fig. 5c) it is clear that the ice-shelf front had receded as far back as these pre-existing rifts and these rift systems defined the maximum inland collapse position.

Changes in ice-shelf tributary glaciers between February 2000 and April 2002

The former tributary glaciers to the Larsen B ice shelf now form calving fronts in the Larsen embayment. The temporal transition from ice-shelf tributary glacier to calving glacier is exemplified by the Hektoria/Green/Evans glacier system. In February 2000, this glacier was one of the main tributaries of the former Larsen B ice shelf (Fig. 7a). Spreading crevasses indicate the onset of extensional flow at the point where the glacier enters the ice shelf. Longitudinal surface structures developed in the main trunk of Hektoria Glacier can be traced all the way to the ice-shelf front (Fig. 3a). Down-glacier, there is an irregular surface topography composed of ridges and depressions inherited from the closed crevasses and longitudinal surface structures (Fig. 3a). Meltwater ponds occupy these surface depressions (Fig. 7a). There is little visible change between the situation in February 2000 and January 2001 (Fig. 7b). By April 2002, following the collapse of the Larsen B ice shelf, Hektoria Glacier formed a large calving front (Fig. 7c). Large transverse rifts and crevasses are visible in the glacier behind the newly formed calving front.

Fig. 7. The temporal transition from ice-shelf tributary to calving glacier at the Hektoria/Green/Evans glacier system. (a) Spreading crevasses at the point where the glacier entered the former Larsen B ice shelf in February 2000. (b) A similar pattern of spreading crevasses visible in January 2001. (c) ‘New’ calving front of the glacier in April 2002 after the collapse of the Larsen B ice shelf. Location of newly formed transverse crevasses and rifts behind the calving front are indicated by arrows.

Upstream of the grounding line, crevasse changes indicate significant changes in the stress regime of the glacier in the aftermath of ice-shelf loss. This is particularly evident in Hektoria Glacier, the most rapidly accelerating glacier of the Larsen B ice shelf tributaries after the collapse. Comparison of pre-collapse images (Fig. 3a–c) with the post-collapse image (Fig. 3d) shows that in regions ∼10 km upstream of the grounding line there was a rapid transition from shear-dominated crevasse styles (Fig. 3a–c) to widespread transverse fracturing indicative of much lower longitudinal back-stress (Fig. 3d). As noted by Reference Rignot, Casassa, Gogineni, Krabill, Rivera and ThomasRignot and others (2004) and Reference Scambos, Bohlander, Shuman and SkvarcaScambos and others (2004) this was associated with velocity acceleration of a factor of 5–8 in the 18 months following break-up and significant (tens of metres) ice surface lowering.

Interpretation of Key Structures and their Significance for Ice-Shelf Collapse

Longitudinal surface structures

Longitudinal surface structures inherited from the tributary glaciers are the dominant flow-related feature on the surface of the ice shelves (Fig. 3a–c). This structure, also previously referred to as flow stripes, flowbands, flowlines or streak lines (Reference Crabtree and DoakeCrabtree and Doake, 1980; Reference Reynolds and HambreyReynolds and Hambrey, 1988; Reference Swithinbank, Brunk and SieversSwithinbank and others, 1988; Reference Casassa and BrecherCasassa and Brecher, 1993; Reference Fahnestock, Scambos, Bindschadler and KvaranFahnestock and others 2000), is developed parallel to the margins of individual flow units. On valley glaciers, where a three-dimensional relationship can be demonstrated, these longitudinal surface structures have been termed foliation (Reference Hambrey and GlasserHambrey and Glasser, 2003), but we have avoided this term because we cannot demonstrate that these structures are three-dimensional. One of the most striking attributes of these features is their persistence; in many cases, the longitudinal structures can be followed for ∼100 km from their origin in tributary glaciers to the ice-shelf front. We infer that where these features are present, tributary glaciers are fast-flowing or active and that where they are absent tributary glaciers are less active.

The physical explanation for the origin of these longitudinal surface structures is unclear. Reference Merry and WhillansMerry and Whillans (1993) considered that these features form in relation to localized high shear strain rates in ice streams near their onset areas. Another possibility is that they represent ‘shear zones’ within individual flow units. However, Reference Casassa and BrecherCasassa and Brecher (1993) found no velocity discontinuities across the boundaries between flow stripes on Byrd Glacier, which suggests that their persistence cannot be explained by lateral shear between the stripes. A more likely explanation is that these structures are created by the visco-plastic deformation or folding of pre-existing inhomogeneities, i.e. primary stratification, under laterally compressive and longitudinally tensile stresses (Reference HambreyHambrey, 1977; Reference Hooke and HudlestonHooke and Hudleston, 1978). The structures may be formed by this mechanism where ice flow interacts with a bedrock feature at some point upstream; shear and compressive forces create an inhomogeneity within the ice that persists for long distances in the absence of any downstream overprinting. Longitudinal surface structures are therefore common and long-lived on ice streams and fast-flowing glaciers where stress and bedrock interactions tend to be small. They are formed upstream as the glacier begins rapid flow and persist downstream because fast-flowing glaciers and ice streams have lower stresses. Further investigation of these features (e.g. using ice-penetrating radar to investigate their three-dimensional structure) is required to establish their precise origin.

Surface meltwater features (streams, ponds and dolines)

Meltwater features clearly indicate the presence of abundant ice-shelf surface melting in the years prior to ice-shelf collapse, an interpretation confirmed by nearby automatic weather station readings (Reference Van den BroekeVan den Broeke, 2005). The precise form and location of meltwater ponds and streams is closely related to glacier surface structures. For example, enclosed meltwater ponds form preferentially on the ice-shelf surface in the Crane Glacier domain because here the ice-shelf surface has a rough, pock marked surface inherited from upstream crevasses and longitudinal surface structures. On the Hektoria/Green/Evans glacier system domain (domain 5 in Fig. 2), where the ice-shelf surface is smoother, both surface meltwater ponds and streams exist (Fig. 3a and b). Thus the ice-shelf surface is dominated by many small ponds (1381 individual meltwater ponds with a total surface area of 251 km2 in January 2000, and 2696 individual meltwater ponds with a total surface area of 365 km2 in February 2000).

In other places, where longitudinal surface structures dominate and in regions of low ice input from upstream sources, meltwater ponds do not form and instead linear meltwater streams follow these structures (Fig. 3a and b). Long, linear meltwater streams also form close to the ice-shelf front where the ice-shelf surface slopes downward towards the ice-shelf front. Close to the ice-shelf front, crevasses and rifts cross-cut the meltwater streams and ponds (Fig. 4b). From this cross-cutting relationship, we infer that the fractures are younger than the meltwater features. Here there is no direct evidence that the fractures are being opened up by meltwater streams or by meltwater ponds draining into rifts and crevasses (Reference MacAyeal, Scambos, Hulbe and FahnestockMacAyeal and others, 2003), so, if this is occurring, it must be at a scale smaller than the resolution of the images used here. Instead, the rifts and crevasses appear to open up sub-parallel to the ice-shelf front under the influence of some other tensional regime, possibly related to extensional flow at the ice-shelf front.

Tributary-glacier rift systems

We suggest that the rifts opened up in these locations because of the strong lateral shear imparted on the less-active zones by the more-active flow units. These areas represent places where the ice shelf was in effect ‘ripped’ open between the active flow units to either side. We do not know the precise composition or mechanical strength of the melange that occupies these rifts, but it appears to contain ‘calved’ icebergs, brash ice, refrozen surface meltwater, blown snow and marine water. The melange within these rifts is re-incorporated into the ice shelf as the rifts are advected down-ice by ice-shelf flow. From the open water and brash ice observed in the upstream-most parts of the inter-domain rifts, we infer that the ice shelf was relatively thin in these areas and unlikely to provide much mechanical strength to the shelf (cf. Reference Jezek and LiuJezek and Liu, 2005).

An important observation is the lack of downstream rift ‘shadows’ at both Foyn Point and Cape Disappointment. The absence of these downstream shadows indicates that these rifts are relatively new features of the ice shelf, formed within the last ∼20 years. This is not the case on other ice shelves, for example the Ross or Ronne Ice Shelf where rift patterns can be traced down-ice for hundreds of kilometres, indicating centuries of steady behaviour (Reference Fahnestock, Scambos, Bindschadler and KvaranFahnestock and others, 2000). When coupled with the ice-velocity data, these rifts, and their absence downstream, suggest that the ice shelf began to change significantly ∼20 years ago. This is consistent with the time when melt ponding began to become widespread across the ice-shelf surface (Reference MacAyeal, Scambos, Hulbe and FahnestockMacAyeal and others, 2003; Reference Van den BroekeVan den Broeke, 2005) and may correlate with thinning of the ice shelf due to warmer water infiltration (Reference Williams, Warner and BuddWilliams and others, 2002; Reference Shepherd, Wingham, Payne and SkvarcaShepherd and others, 2003; Reference Payne, Vieli, Shepherd, Wingham and RignotPayne and others, 2004).

The evidence of relatively recent development of the tributary rift systems from the imagery suggests that the sutures were weakened significantly in the years leading up to the collapse in 2002. Thus the incremental loss of ice-shelf front may be enough to increase susceptibility to breakup because the loss of ice-shelf front causes increased shear and decoupling of the upstream suture areas with the coast.

Ice-shelf front rifts

Rifts close to the ice-shelf front, such as those shown in Figure 4, propagate as the ice shelf flexes because of ice-shelf deformation during horizontal motion (Reference Rist, Sammonds, Oerter and DoakeRist and others, 2002; Reference Larour, Rignot and AubryLarour and others, 2004). They are important because rift spacing strongly influences the dimensions of icebergs, as well as the frequency and magnitude of iceberg-calving events (Reference WeissWeiss, 2004).

Ice-shelf tributary domains

Tributary-glacier domains on the ice-shelf surface are marked by the longitudinal surface structures visible within individual tributary-glacier flow units. Longitudinal surface structures originating in the trunks of these glaciers can be traced, uninterrupted, all the way to the ice-shelf front, implying that these glaciers are fast-flowing and actively contribute mass to the ice shelf. Splaying crevasse patterns and bowed longitudinal surface structures also indicate that there is divergence of flow as these glaciers enter the ice shelf (Fig. 2). Between the active domains are domains lacking significant up-glacier catchments and without longitudinal surface structures, inferred to represent slower-flowing or less-active flow units. The structural evidence agrees with earlier field- and satellite-derived velocity and longitudinal strain-rate measurements, which have established that individual flow units on the former Larsen B ice shelf had markedly different velocity, longitudinal strain rates and rheology (e.g. Reference Bindschadler, Fahnestock, Skvarca and ScambosBindschadler and others, 1994; Reference Skvarca, Rack and RottSkvarca and others, 1999; Reference Rack and RottRack and Rott, 2004; Reference Vieli, Payne, Du and ShepherdVieli and others, 2006, Reference Vieli, Payne, Shepherd and Du2007; Reference Khazendar, Rignot and LarourKhazendar and others, 2007).

Our velocity measurements (Fig. 6) and the presence of open-rift systems in the zones between the more-active and less-active flow units around Foyn Point and Cape Disappointment support the interpretation that velocity and longitudinal strain rates differ between flow units. We suggest that the rifts formed in these locations because of the strong lateral shear imparted on the less-active zones by the more-active flow units.

Finally, we note that by far the largest contribution to the ice shelf comes from only four tributary glaciers: the Hektoria/Green/Evans glacier system (domain 5 in Fig. 2), Punchbowl Glacier (domain 7 in Fig. 2), Jorum Glacier (domain 8 in Fig. 2) and Crane Glacier (domain 10 in Fig. 2).

Changes in ice-shelf tributary glaciers between February 2000 and April 2002

Following the collapse of the Larsen B ice shelf, former tributary glaciers such as Hektoria/Green/Evans, Jorum and Crane glaciers now form large calving fronts in the Larsen embayment (Fig. 7c). Large transverse rifts and crevasses in these glaciers behind the newly formed calving front indicate longitudinal extension. This type of extension is compatible with the finding that tributary glaciers have thinned and accelerated considerably since ice-shelf collapse (Reference Thomas, Sanderson and RoseThomas and others, 1979; Reference Van der VeenVan der Veen, 1996; Reference Rignot, Casassa, Gogineni, Krabill, Rivera and ThomasRignot and others, 2004; Reference Scambos, Bohlander, Shuman and SkvarcaScambos and others, 2004). The presence of an ice shelf provides back-stress or decreases the magnitude of the extensional stress near the grounding line and therefore inhibits glacier motion behind the ice shelf (Reference Dupont and AlleyDupont and Alley, 2005). Once this buttressing effect is removed, the tributary glaciers are free to accelerate. The volume of calved icebergs immediately in front of the glacier indicates that calving is an active and ongoing process.

Discussion

Ice-shelf collapse: structural precursors

We have defined domains on the Larsen B ice shelf related to glacier-source areas (Fig. 2) and have demonstrated that, prior to collapse, the largest contribution to the ice shelf came from only four tributary glaciers: the Hektoria/Green/Evans glacier system, Punchbowl Glacier, Jorum Glacier and Crane Glacier. Between these glacier-fed active flow units were less-active flow units. The active flow units were sutured downstream. In recent years, thinning of the ice shelf, and, just prior to collapse, loss of the ice-front region of the ice shelf, led to a much weaker shelf, prone to extension and fracturing.

Unless the upstream regions of sutures between individual flow units were strong, which we consider unlikely, these structural discontinuities would have rendered the ice shelf mechanically weak, and therefore prone to disintegration, prior to its collapse. Failures developed along the flow-unit boundaries, which were only weakly sutured, so ice-shelf collapse proceeded rapidly along these lines of structural weakness. The decoupling of the suture regions from the coast around Foyn Point and Cape Disappointment is a potential indicator of impending ice-shelf break-up. On the existing Larsen C ice shelf we note that tributary suture regions do not, at present, show the rifting and melange that we observed in the pre-collapse Larsen B. This would indicate that the Larsen C ice shelf is probably not in immediate danger of collapse. There is, however, some indication of new ‘tributary junction’ rifting in the remnant Larsen B ice shelf, which may indicate a potential for further recession of that ice shelf.

Ice-shelf susceptibility to break-up was also increased by mass loss at the ice-shelf front because the loss of ice at the shelf front removed the strongest portions of the shelf, i.e. the most sutured, bonded and thickened (by accumulation) portions in the inter-domain regions. An important observation of ice-shelf disintegration is that it occurred through the formation of many narrow, needle-shaped icebergs instead of the large tabular icebergs that characterized pre-collapse iceberg calving. The structural features that we have observed (e.g. the very long, closely spaced rifts and crevasses) mirror the size of many of the icebergs formed during disintegration and therefore help to explain the dramatic change in the size distribution of Larsen B ice shelf icebergs before and during collapse.

Even if our assertion that the Larsen B ice shelf was mechanically weak prior to its collapse is correct, a trigger is still required for its sudden and rapid disintegration. The leading hypothesis for this rapid disintegration is that of Reference Scambos, Hulbe, Fahnestock and BohlanderScambos and others (2000) and Reference MacAyeal, Scambos, Hulbe and FahnestockMacAyeal and others (2003), who proposed that ponded meltwater on the ice-shelf surface acted as a mechanical force in the crevasses, causing breaks in the ice shelf and thus accelerating ice-shelf disintegration. However, another hypothesis emerges from our structural analysis. This is the possibility that ice-shelf collapse may have been initiated along structural lines, either by ice-shelf acceleration or by perturbations in the input velocity from one or more of the tributary-glacier flow units. A rapid or sustained period of acceleration or deceleration of one of these tributary glaciers or change in the longitudinal stress regime would be sufficient to cause the suture between flow units to rupture (especially in a climatically thinned ice shelf; cf. Reference Vieli, Payne, Shepherd and DuVieli and others, 2007) and thus cause the ice shelf to disintegrate along pre-existing lines of structural weakness.

There is independent evidence to support this hypothesis from three sources. First are pre-collapse stake measurements on the former Larsen B ice shelf, which show disturbances in mass balance and ice-flow behaviour in the years prior to collapse (Reference Rack, Doake, Rott, Siegel and SkvarcaRack and others, 2000). Second are satellite-derived ice-shelf velocities that clearly show pre-collapse velocity differentials between individual ice-shelf tributary glaciers for the adjacent Larsen A ice shelf (Reference Bindschadler, Fahnestock, Skvarca and ScambosBindschadler and others, 1994). Third are the satellite observations and modelling experiments of Reference Vieli, Payne, Shepherd and DuVieli and others (2007) that indicate the ice shelf was undergoing a significant acceleration before its collapse in 2002.

We suggest that a number of atmospheric, oceanic and glaciological factors contribute to ice-shelf collapse (Fig. 8). Rapid ice-shelf disintegration is aided by structural factors, as well as the large quantities of surface meltwater observed on the ice shelf in 2002 (Reference MacAyeal, Scambos, Hulbe and FahnestockMacAyeal and others, 2003; Reference Van den BroekeVan den Broeke, 2005). A related possibility is that changes in velocity structure were initiated by external factors such as ocean warming (Reference Williams, Warner and BuddWilliams and others, 2002; Reference Shepherd, Wingham, Payne and SkvarcaShepherd and others, 2003; Reference Payne, Vieli, Shepherd, Wingham and RignotPayne and others, 2004) or transoceanic wave propagation (Reference MacAyealMacAyeal and others, 2006). It is probably not possible to ascribe ice-shelf collapse singularly to one of these factors. It is therefore possible that in 2002 the Larsen B ice shelf simply crossed an environmental threshold where the interplay between atmospheric factors (e.g. increased surface melting and associated ice-shelf thinning), oceanic factors (e.g. increased bottom melting and associated ice-shelf thinning and recession, as well as the potential for increased iceberg calving) and glaciological factors (e.g. differences in upstream surface mass balance and velocity between flow units, and structural weaknesses) was sufficient to cause an irreversible decline.

Fig. 8. Flow diagram showing factors influencing ice-shelf collapse. Items within shaded areas represent causal factors. See text for full discussion.

Conclusions

In this study we have provided a detailed structural glaciological analysis of the changes in surface structures on the Larsen B ice shelf from a series of visible-channel satellite images acquired between January 2000 and April 2002 and the RADARSAT-1 Antarctic Mapping Project (RAMP) mosaic of 1997. Mapped structures include longitudinal surface structures, rifts, crevasses, meltwater streams, meltwater ponds and dolines. Longitudinal surface structures are particularly important on the Larsen B ice shelf because they can be used to define individual tributary-glacier flow units (domains) and their contribution to the pre-collapse ice shelf. Using these data, we draw the following conclusions:

  1. 1. The former Larsen B ice shelf consisted of four sutured flow units fed by Crane Glacier, Jorum Glacier, Punchbowl Glacier and the Hektoria/Green/Evans glacier system. Between these active glacier-fed flow units were ‘suture zones’ of thinner ice where the feeder glaciers merged to form the shelf.

  2. 2. Prior to collapse, large open-rift systems (with floating brash ice) were present offshore of Foyn Point and Cape Disappointment. In the years just preceding break-up, these rifts became more pronounced and ice blocks in the rifts rotated because of the strong lateral shear in the zone separating active and less-active flow units. Velocity mapping of the suture regions indicates that the major rifts are a recent feature of the ice shelf, and were not present over ∼20 years ago.

  3. 3. The geographical extent of the ice-shelf collapse was controlled partly by the location of these large open-rift systems offshore of Foyn Point and Cape Disappointment. When the ice shelf collapsed, disintegration proceeded as far back as these rifts.

  4. 4. A number of factors (atmospheric, oceanic and glaciological) combined to contribute to the rapid demise of the Larsen B ice shelf in 2002. We suggest that structural glaciological discontinuities played a large part because they rendered the ice shelf mechanically weak prior to its collapse. Failures along weakly sutured flow-unit boundaries were particularly important. Loss of ice at the shelf front may also have played a role because this process removed the strongest portions of the shelf, i.e. the most sutured and bonded portions in the inter-domain regions.

  5. 5. Ice-shelf collapse may have been initiated by perturbations in the input velocity from one or more of the tributary-glacier flow units, which caused the sutures between flow units to rupture and thus caused the ice shelf to disintegrate rapidly.

Acknowledgements

N.F. Glasser acknowledges support from the US–UK Fulbright Commission as a Fulbright Distinguished Scholar at the US National Snow and Ice Data Center in 2007 and from a CIRES (Cooperative Institute for Research in Environmental Sciences) Research Fellowship. D. Quincey helped with the production of Figure 6. We acknowledge constructive reviews from J. Bassis and D. Vaughan. T. Scambos acknowledges support from NASA grant NNG06GA69G.

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Figure 0

Fig. 1. Portion of the 1997 RAMP (RADARSAT-1 Antarctic Mapping Project) mosaic showing the Antarctic Peninsula and place names mentioned in the text. The location of the mapped area shown in Figure 2 is indicated.

Figure 1

Table 1. Details of satellite images used in this study

Figure 2

Table 2. Features mapped on the satellite images, together with their identification criteria and possible significance

Figure 3

Fig. 2. Tributary-glacier domains on the former Larsen B ice shelf inferred from crevasse patterns and longitudinal surface structures on ASTER mosaic in November 2001. Numbers refer to domains discussed in the text.

Figure 4

Fig. 3. Sequence illustrating the changes in surface structures on the Larsen B ice shelf between January 2000 and April 2002. (a) Structural interpretation from January 2000. (b) Structural interpretation from February 2000. Numbers 1–9 refer to features on the surface of the ice shelf discussed in the text. Boxes indicate the locations of other figures. (c) Structural interpretation from November 2001. (d) Structural interpretation from April 2002. Note that there is little change in the position of the ice-shelf edge between February 2000 and November 2001 but that the number of rifts and crevasses near the ice-shelf edge has increased by November 2001. By April 2002 the ice shelf has completely disappeared. Numbers refer to localities discussed in the text.

Figure 5

Fig. 4. Changes near the edge of the Larsen B ice shelf between February 2000 and November 2001. (a) Detail of Landsat image acquired in February 2000. Arrow 1 indicates doline; arrow 2 indicates rifts cutting through meltwater streams. (b) Interpretation of the same area. Note that close to the ice-shelf edge the crevasses and rifts are sub-parallel to the ice-shelf edge and cross-cut the meltwater streams and ponds. (c) Detail of ASTER image acquired in November 2001. (d) Interpretation of the same area. Note that there are more rifts close to the ice-shelf edge than in the comparable scene from February 2000.

Figure 6

Fig. 5. (a, b) Detail of the southern part of Larsen B ice shelf prior to ice-shelf collapse in February 2000 (a) and November 2001 (b). (c) The situation after ice-shelf collapse in April 2002. Note that large rift systems containing open water and calved icebergs, labelled 1 and 2 in (a), existed prior to ice-shelf collapse. Note also the rotation of the blocks within the rifts around area 2 between February 2000 and November 2001. The rifts later formed the inward limit of ice-shelf collapse (c).

Figure 7

Fig. 6. Ice-velocity measurements in the Foyn Point and Cape Disappointment regions between 21 February 2000 and 22 November 2001 using image-to-image cross-correlation techniques (Scambos and others, 1992). Dots indicate ice-motion measurement vector midpoints from which the velocity fields were interpolated.

Figure 8

Fig. 7. The temporal transition from ice-shelf tributary to calving glacier at the Hektoria/Green/Evans glacier system. (a) Spreading crevasses at the point where the glacier entered the former Larsen B ice shelf in February 2000. (b) A similar pattern of spreading crevasses visible in January 2001. (c) ‘New’ calving front of the glacier in April 2002 after the collapse of the Larsen B ice shelf. Location of newly formed transverse crevasses and rifts behind the calving front are indicated by arrows.

Figure 9

Fig. 8. Flow diagram showing factors influencing ice-shelf collapse. Items within shaded areas represent causal factors. See text for full discussion.