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Selective erosion beneath the Antarctic Peninsula Ice Sheet during LGM retreat

Published online by Cambridge University Press:  13 November 2014

Nicholas R. Golledge*
Affiliation:
Antarctic Research Centre, Victoria University of Wellington, PO Box 600, Wellington 6140, New Zealand GNS Science, PO Box 30-368, Lower Hutt 5040, New Zealand
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Abstract

In mountainous terrain, the relationship between ice sheet dynamics and basal topography is complex, with each component influencing the other. This paper investigates how the last glacial maximum Antarctic Peninsula Ice Sheet might have modified its bed both at maximum extent and during progressive grounding line retreat. Focussing on the Marguerite Trough Ice Stream we then examine the degree to which basal topographical conditions affected the rate of ocean-forced recession. Zones of peak subglacial erosion are preferentially located in areas of convergent flow and where horizontal strain rates are highest. During ice sheet retreat, potential erosion rates increase in these areas, but the foci remain fixed. This leads to selective and progressive deepening of subglacial basins. As grounding lines migrate landward, faster retreat tends to occur over subglacial basins, especially if flow is divergent, whereas slower retreat takes place on sloping beds and where the geometry of the outlet allows convergent flow and a non-negative flux balance. In conclusion the Antarctic Peninsula Ice Sheet selectively erodes its bed beneath linear outlets and, over successive glacial cycles, progressive deepening of subglacial basins may bring about non-linear retreat of the ice sheet margin.

Type
Original Article
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/3.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
© Antarctic Science Ltd 2014

Introduction

The notion that ice sheets can differentially modify their beds through the course of repeated glaciations has been around since the earliest observations of terrestrial glaciations (Agassiz Reference Agassiz1841), but systematic mapping, interpretation and synthesis of the geomorphological evidence indicative of such behaviour has advanced most notably through a comprehensive exploration of the subject spanning almost half a century (Sugden Reference Sugden1968, Reference Sugden1978, Jamieson et al. Reference Jamieson, Hulton, Sugden, Payne and Taylor2005, Reference Jamieson, Sugden and Hulton2010, Sugden et al. Reference Sugden, Balco, Cowdery, Stone and Sass2005, Phillips et al. Reference Phillips, Hall, Mottram, Fifield and Sugden2006). Collectively this body of work put forward, developed and tested the concept of ‘selective linear erosion’ by glaciers, in which successive glacial cycles repeatedly focused erosion beneath wet-based ice occupying deep troughs. Over time, this concentrates erosion along valley floors, whilst neighbouring upland areas remain relatively unscathed due to their cover of thinner, colder and less erosive ice. Following directly from the earliest of these insights and building on later expansions of the theory, many recent studies now report observations of differential subglacial erosion (Fabel et al. Reference Fabel, Stroeven, Harbor, Kleman, Elmore and Fink2002, Briner et al. Reference Briner, Miller, Davis and Finkel2006, Stroeven et al. Reference Stroeven, Harbor, Fabel, Kleman, Hättestrand, Elmore, Fink and Fredin2006, Licht & Palmer Reference Licht and Palmer2013) or describe numerical simulations that attempt to either quantify or explain the process (Alley et al. Reference Alley, Lawson, Larson, Evenson and Baker2003, Bougamont & Tulaczyk Reference Bougamont and Tulaczyk2003, Bougamont et al. Reference Bougamont, Tulaczyk and Joughin2003, Pollard & DeConto Reference Pollard and Deconto2003). Furthermore, it is becoming increasingly apparent that subtleties of basal topography may in turn condition the behaviour of an overlying ice sheet, for example through stabilizing feedbacks, such as sedimentation at glacier grounding lines (Alley et al. Reference Alley, Lawson, Larson, Evenson and Baker2003, Reference Alley, Anandakrishnan, Dupont, Parizek and Pollard2007). In these scenarios, continued subglacial transport of sediment to the grounding line buffers the glacier from minor changes in sea level, building a sedimentary wedge that ‘fills in’ the gap beneath the ice-shelf base and the sea floor. This essentially makes the ocean shallower at such locations, and thus a greater sea level rise is required to destabilize the glacier margin. The ice sheet–topography system is therefore complex, and influences operate in both directions.

Numerical modelling presents an ideal approach with which to investigate ice sheet–topography interactions. Yet, until recently, computational demands have limited the spatial resolution of continental-scale ice sheet simulations to grids that allow tractable experimentation which, in the case of continents such as Antarctica, has typically been 20–40 km (Huybrechts Reference Huybrechts2002, Pollard & DeConto Reference Pollard and Deconto2009). At this scale, major outlet glaciers are simulated, but finer details are lost. Thus numerical replication of selective linear erosion at a scale observable in the field has remained to some extent unachievable. Computational advances now make it possible to simulate continental ice sheets at a scale that can be compared to field observations (e.g. Golledge et al. Reference Golledge, Levy, McKay, Fogwill, White, Graham, Smith, Hillenbrand, Licht, Denton, Ackert, Maas and Hall2013), meaning that geomorphological questions can now be addressed more easily.

The principal aim of this paper is to use high-resolution (5 km), whole-continent Antarctic ice sheet simulations to explore the changing geometry and dynamics of the Antarctic Peninsula Ice Sheet (APIS) through the last glacial termination. The specific objectives are to: i) identify the pattern of ice flow at the Last Glacial Maximum (LGM, c. 20 ka) and its consequence in terms of probable subglacial erosion, and ii) determine how the speed of ice sheet retreat following the LGM may have been modulated by topographical feedbacks.

Study area

The Antarctic Peninsula is characterized by a linear mountain chain and numerous outlying islands (Fig. 1a). Summits in Palmer Land rise to over 3000 m above sea level (a.s.l.), and accumulate ice preferentially on their western flanks as a consequence of a relatively high precipitation rate (Arthern et al. Reference Arthern, Winebrenner and Vaughan2006, Lenaerts et al. Reference Lenaerts, van den Broeke, van de Berg, van Meijgaard and Munneke2012). Eastern slopes accommodate more modest glaciers due to the drier regional atmospheric conditions. The western continental shelf is more deeply incised than in the east, with well-developed linear troughs (e.g. Marguerite Trough) extending from present-day coastal areas to the continental shelf-break. Evidence from trough-mouth fans suggests that these troughs have been repeatedly occupied by ice streams throughout the Cenozoic (Livingstone et al. Reference Livingstone, Ó Cofaigh, Stokes, Hillenbrand, Vieli and Jamieson2012).

Fig. 1 a. Bed topography of the Antarctic Peninsula and surrounding continental shelf, from Fretwell et al. (Reference Fretwell, Pritchard and Vaughan2013). Thin black lines show modern coast and grounding lines (Haran et al. Reference Haran, Bohlander, Scambos and Fahnestock2005), dashed black line indicates modelled Last Glacial Maximum (LGM) margin position (Golledge et al. Reference Golledge, Fogwill, Mackintosh and Buckley2012a). AI=Alexander Island, BC=Bryan Coast, EIS=Evans Ice Stream, GVIS=George VI Sound, LIS=Larsen Ice Shelf, MB=Marguerite Bay, MT=Marguerite Trough. b. Modelled surface elevation and flow-lines of grounded ice (ice shelves shown in black). c. Modelled horizontal ice flux at the LGM (Golledge et al. Reference Golledge, Fogwill, Mackintosh and Buckley2012a). d. Transient grounding line positions during modelled retreat, driven by increasing oceanic temperature and rising sea level

Ice sheet model and experimental design

We use the Parallel Ice Sheet Model (PISM; Bueler & Brown Reference Bueler and Brown2009), a 3D Eulerian finite difference model that is purposely designed to enable high-resolution and long-term simulations of ice sheet flow. This model has been successfully applied to a wide variety of glaciological research, including high-resolution simulations of the Greenland and Antarctic ice sheets (Golledge et al. Reference Golledge, Fogwill, Mackintosh and Buckley2012a, Bueler et al. unpublished) and of mountain ice fields (Golledge et al. Reference Golledge, Mackintosh, Anderson, Buckley, Doughty, Barrell, Denton, Vandergoes, Andersen and Schaefer2012b). PISM combines the shallow approximations of ice sheet (SIA) and ice-shelf (SSA) flow (Bueler & Brown Reference Bueler and Brown2009), so that grounded ice is influenced both by gravitational and longitudinal stresses, whereas floating ice is solely governed by the latter (i.e. spreading forces). This combination approach to ice sheet stress balance allows both sheet and shelf flow to be simulated, as well as that of transitional zones such as ice streams where ice is grounded (like an ice sheet) but has very low basal drag (like an ice shelf). An enhancement factor of three was used for the SIA, based on parameter tuning experiments (Golledge et al. Reference Golledge, Fogwill, Mackintosh and Buckley2012a), with no explicit calving of ice shelves imposed except to limit their extent to within the continental shelf area. Recently, the ability of 3D ice sheet models (such as PISM) to accurately track grounding line migrations has been investigated using simplified geometry experiments (Pattyn et al. Reference Pattyn, Perichon and Durand2013). Those simulations revealed that few finite-difference ice sheet models were capable of accurately tracking grounding line movements over short time frames and at coarse resolutions. In our implementation we hope to have mitigated some of these shortcomings by running long (multi-millennial) integrations and by using a relatively fine (5 km) spatial grid, but this remains an area where continued model refinement is required.

The simulations presented and described here are from a suite of experiments that were initialized from a thermally-equilibrated and dynamically-stable 20km resolution present-day configuration Antarctic ice sheet. This spun-up model was then allowed to re-equilibrate under environmental conditions representative of the LGM. The magnitude of imposed LGM atmospheric cooling was based on the Vostok d18O time series (Petit et al. Reference Petit, Jouzel, Raynaud, Barkov, Barnola, Basile, Bender, Chappellaz, Davis, Delaygue, Delmotte, Kotlyakov, Legrand, Lipenkov, Lorius, Pepin, Ritz, Saltzman and Stievenard1999), oceanic cooling from stacked global benthic d18O records (Lisiecki & Raymo Reference Lisiecki and Raymo2005), and long-term sea level changes from Imbrie & McIntyre (Reference Imbrie and McIntyre2006). From this steady-state LGM Antarctic ice sheet simulation we then simulated its dynamic response to a range of ocean-forcing perturbations in the form of sea level and oceanic temperature changes. Since the experiments were designed simply to examine the response of the modelled ice sheet to isochronous perturbations, arbitrary sea level increases of 25 and 50 m, and increases in sub-shelf melting (representing oceanic heat flux) of 33, 67 and 100% of the LGM to present difference were used.

Calculation of potential subglacial erosion

One way to infer the probable erosional effects of the LGM APIS is to consider subglacial erosion of bedrock as a function of basal ice velocity and the shearing force exerted at the bed (Pollard & DeConto Reference Pollard and Deconto2003):

(1) $$\eqalignno { \theta \,=\,{\rm }\left( {{\rm 1}\,{\rm -}\,\left( {S/T_{{lim}} } \right)} \right)\,{\rm x}\,{\rm 2}e^{{{\hbox - }{\rm 1}0}} \tau _{b} U_{s} (1)$$

Here, bedrock erosion rate (θ) is dependent on ice geometry and dynamics, and the thickness of eroded material (S) which evolves until a maximum limiting threshold is reached (T lim ). Basal shear stress (τ b ) and the sliding velocity (U s ) that arises from it are calculated from the combined stress balance approach described above and in Bueler & Brown (Reference Bueler and Brown2009). In the above scheme, subglacial erosion potential under an ice sheet in equilibrium will depend primarily on its sliding speed, thickness and surface slope, but the actual amount of bedrock erosion that might occur will be further controlled by the thickness and rheology of overlying sediments as well as the coherency and erodibility of the rock type being overridden. Since these latter two components are largely unknown, except where geophysical studies have allowed local interpretations to be made, we focus here on calculating the glaciological component of subglacial erosion potential. These results are presented with dimensionless units to acknowledge that alternative parameterizations would yield different results. However, it is the relative pattern of erosion potential that is most important in this study, manifest in the different rates that characterize different areas.

Landscape preservation

A primary aim of this study is to investigate the likely pattern of bedrock erosion, as defined above, and the dominant controls that influence landscape evolution. Previous attempts at the interpretation of landscape preservation beneath former ice sheets have commonly invoked favourable basal thermal conditions (i.e. a frozen bed) as the primary control (Dyke Reference Dyke1993, Kleman Reference Kleman1994, Kleman & Hättestrand Reference Kleman and Hättestrand1999, Ó Cofaigh et al. Reference Ó Cofaigh, Dowdeswell and Pudsey2001, Davis et al. Reference Davis, Briner, Coulthard, Finkel and Miller2006, Reinardy et al. Reference Reinardy, Pudsey, Hillenbrand, Murray and Evans2009), yet numerous process studies have reported observations of subglacial motion (and thus the potential for erosion) or evidence of bed modification at subfreezing temperatures (Shreve Reference Shreve1984, Echelmeyer & Wang Reference Echelmeyer and Wang1987, Cuffey et al. Reference Cuffey, Conway, Hallet, Gades and Raymond1999, Atkins et al. Reference Atkins, Barrett and Hicock2002, Fitzsimons Reference Fitzsimons2003, Atkins Reference Atkins2013). In the theoretical analysis of Shreve (Reference Shreve1984), who calculated sliding speeds for ice at temperatures as low as 20°C below the pressure-melting point, it was demonstrated that sliding could occur at such temperatures because of basal water films as thin as 1 nm (1x10-9 m). Although basal velocities of subfreezing glaciers are typically low, their erosion potential may be significant over millennial timescales, particularly in areas where the overlying ice is thick (e.g. >1 km).

Role of topography in ice-stream retreat

The Marguerite Trough Ice Stream (MTIS) has received considerable attention both in terms of field-based geological investigations (Ó Cofaigh et al. Reference Ó Cofaigh, Dowdeswell, Allen, Hiemstra, Pudsey, Evans and Evans2005, Anderson & Fretwell Reference Anderson and Fretwell2008, Kilfeather et al. Reference Kilfeather, Ó Cofaigh, Lloyd, Dowdeswell, Xu and Moreton2011) as well as modelling studies (Payne et al. Reference Payne, Sugden and Clapperton1989, Jamieson et al. Reference Jamieson, Vieli, Livingstone, Ó Cofaigh, Stokes, Hillenbrand and Dowdeswell2012). The consensus of this body of research is that the ice stream was sourced in the central mountains of Palmer Land, drained into George VI Sound, flowed northward into Marguerite Bay, and from there towards the continental shelf break (Fig. 3a). Weak deformation till and the presence of mega-scale glacial lineations attest to the fast flow of this outlet (Ó Cofaigh et al. Reference Ó Cofaigh, Dowdeswell, Allen, Hiemstra, Pudsey, Evans and Evans2005), whilst the occurrence of meltwater channels incised into both soft sediment and bedrock led Anderson & Fretwell (Reference Anderson and Fretwell2008) to infer a well developed subglacial hydraulic network beneath the MTIS. Submarine geomorphology is also characterized by well developed grounding zone wedges, which may have stabilized the ice stream during periods of episodic retreat (Jamieson et al. Reference Jamieson, Vieli, Livingstone, Ó Cofaigh, Stokes, Hillenbrand and Dowdeswell2012). Here we use our continental-scale model to investigate this particular ice stream system in the context of topographic control on ice sheet behaviour.

Results

The Antarctic Peninsula Ice Sheet at the last glacial maximum

The relatively low aspect-ratio of the simulated LGM APIS means that ice discharging from central accumulation areas is topographically controlled to a greater extent in western areas than in the east. Modelled flow-lines illustrate the effect of this topographical influence, preferentially funnelling ice through troughs (Fig. 1b). This pattern of basal control on ice flow is much less apparent on the Weddell Sea side of the APIS, where instead ice appears to flow more or less directly towards the continental shelf-break. In the east, ice flow from the southern APIS converges with ice from West Antarctica to flow northward through an extended Evans Ice Stream; in the west, glaciers draining the Bryan Coast of West Antarctica discharge into the Bellingshausen Sea.

The modelled pattern of LGM ice flow identifies many individual locations of convergent outlet glaciers and probable ice streams, yet their rates of ice discharge are highly variable. For example, the greater ice thicknesses evident in the southern APIS coupled with higher velocities give rise to a greater horizontal ice flux per unit area than outlets in the northern APIS (Fig. 1c). In terms of discharge volume, the dominant outlets are those draining into the Bellingshausen Sea from Ellsworth Land, the extended Evans Ice Stream in the western Weddell Sea, the Marguerite Trough Ice Stream (MTIS) and to a lesser extent a smaller ice stream sourced from central Alexander Island. Each of these conduits features a well-defined ‘trunk’, and is fed by a number of tributaries. In the MTIS and the two large Bellingshausen Sea outlets, peak fluxes occur in the mid-sections of the glaciers, downstream of their onset zones but upstream of their termini on the continental shelf. By contrast, fluxes in the Evans Ice Stream increase progressively towards the shelf-break.

Subglacial erosion potential

Given the formulation of Eq. (1), it is not surprising that the greatest subglacial erosion is predicted to occur beneath fast-flowing outlets of the LGM APIS (Fig. 2a). In such areas, modelled erosion rates are at least one or two orders of magnitude higher than flanking areas, suggesting that preferential deepening of cross-shelf troughs is probable. Conversely, upland areas, as well as inter-stream sectors, are most likely to be protected from any significant subglacial erosion. This pattern is maintained during retreat of the LGM ice sheet, with zones of erosion potential largely remaining unchanged (Fig. 2b). Considering the central sector of the LGM APIS in more detail, Fig. 3a illustrates that the greatest subglacial erosion potential occurs beneath the central parts of the trunks of the largest outlets, in some cases extending into inland catchments. Beneath the MTIS, erosivity most probably reached a maximum in two locations: one zone at the mouth of George VI Sound and a second in the inner shelf area of Marguerite Bay (Fig. 3a). These locations correspond precisely with peaks in longitudinal strain rates, indicating accelerating flow (Fig. 3b). These zones of peak glacier acceleration do not migrate during deglaciation; rather, their magnitudes are enhanced with respect to ‘steady-state’ conditions at the LGM but their positions remain fixed. During MTIS retreat, along-flow discharge rates increase dramatically in George VI Sound (Fig. 3c) due to the accelerations described above, whereas flux across the continental shelf from Marguerite Bay declines as both ice thickness and horizontal velocity reduces.

Fig. 2 Relative pattern of subglacial erosion potential (Eq. 1) for a. LGM conditions and b. after ocean-forced retreat. Grey shading denotes areas of the ice sheet where calculated erosion potential is more than an order of magnitude below the lowest coloured value (i.e. <0.01).

Fig. 3 a. Pattern of potential Last Glacial Maximum (LGM) subglacial erosion in the central Antarctic Peninsula. AI=Alexander Island, GVIS=George VI Sound, MB=Marguerite Bay. Present-day coastline and LGM flow lines shown in black. Red line illustrates Marguerite Trough Ice Stream (MTIS) centreline. b. Horizontal strain rates along the MTIS centreline at LGM (bold, green) and during stages of ocean-forced retreat (dashed lines). c. Ice discharge rate (flux) along the MTIS at LGM (bold, red) and during retreat (dashed lines). d. MTIS surface and bed profiles at LGM (bold, blue) and during retreat (dashed lines).

Landscape preservation

These simulations indicate that interior areas with little or no subglacial erosion at LGM will be the same as those under a more restricted ice sheet configuration, and thus the underlying landscape in these areas will probably survive unmodified.

To investigate the primary control on subglacial erosion, calculated erosion potential was first plotted at each grid cell against the horizontal ice flux (thicknessxvelocity) in that cell, and each point shaded according to the temperature of basal ice in that location, relative to the pressure melting point (Fig. 4a). There is a clear correlation between erosion potential and ice flux, implying that the greatest modification of the glacier bed is likely to arise wherever ice discharge is high, i.e. where either velocities or thicknesses are greatest. Conversely, landscapes would be protected in areas where fluxes are low, such as in the central parts of ice sheets where velocities are low, or in parts of the ice sheet that are thin, for example over mountain summits. However, the relationship between subglacial erosion potential and basal ice temperature for the simulated LGM APIS is more complex. Whilst the very highest rates of erosion (>1) only occur beneath ice at the pressure melting point, there is no clear relationship at lower temperatures and basal erosion appears to be possible (albeit in relatively few locations) at -10°C and below. This occurs as a consequence of longitudinal stresses. Where fast-flowing wet based ice transitions into slower and colder ice in upstream catchment areas it exerts a pulling force. This allows sliding even at sub-freezing temperatures, in agreement with field observations. Since flow rates are extremely low in these areas, the potential for erosion will be correspondingly small, unless compensated for by a greater thickness of ice. The critical factor appears to be the presence of water at the bed. In our model, ice with a positive sliding velocity also has a basal water layer (Fig. 4b) and the results illustrate that even very thin films of water are sufficient to allow basal motion. However, where these films approach 1 nm, basal velocities are extremely low (Fig. 4c).

Fig. 4 a. Relationship between calculated subglacial erosion potential and the rate of ice discharge, shaded according to temperature of basal ice relative to the pressure-melting point. b. Thickness of basal water layer in relation to basal ice velocity. c. The distribution of basal ice velocities for cells where the subglacial water layer thickness is less than the minimum shown in b.

In summary, it is apparent that temperature alone does not exert complete control over modelled basal erosion potential or the ability of ice sheets to modify or preserve their underlying landscapes. Subfreezing temperatures do not necessarily preclude sliding (and by inference, basal erosion), and conversely, ice at the pressure-melting point does not necessarily lead to significant modification of the glacier bed. What is important in terms of predicting likely erosion patterns is the accurate calculation of horizontal ice flux.

Role of topography in ice-stream retreat

During deglaciation, these model experiments illustrate that, under the range of applied ocean forcing scenarios, grounding line positions tend to retreat gradually in some areas, and more rapidly in others (Fig. 1d). For example, both the outer and inner Bellingshausen Sea appear to favour closely-spaced grounding line positions, whereas the intervening section of continental shelf appears to be a less favourable location for grounded ice margins. Likewise in the western Weddell Sea, the outer part of the shelf appears to allow incremental retreat, whereas the inner shelf is conducive to more abrupt back-stepping of the grounding line. The same pattern is evident seaward of the present-day Larsen Ice Shelf, and at a smaller scale elsewhere around the APIS.

To investigate this in more detail the pattern of retreat of the MTIS along a single modelled flow-line during retreat from its LGM position is considered (Fig. 3a).

These experiments illustrate a series of progressively-retreated grounding line positions that reflect non-linear recession of the grounded ice sheet in response to the imposed oceanic forcings. Many of the 48 simulated grounding line positions overlap, suggesting that some topographic situations favour slower retreat than others (Fig. 3d). The greatest density of grounding line positions occurs on subglacial topographical highs in the inner and outer continental shelf, with far fewer overlapping positions in the deeper mid-shelf. Slower retreat appears to coincide with down-flow dipping beds and the upper parts of retrograde slopes, but is less common on the flat bed and lower parts of flanking slopes of the deep basin of the mid-shelf.

Discussion

Climatic factors appear to have produced asymmetric behaviour of the APIS at the LGM. The wetter western side hosted a larger number of fast-flowing outlet glaciers and ice streams whose positions were topographically determined. The climate and physiography of the eastern APIS gave rise to fewer, but more extensive, areas of fast flow. These differences have no doubt persisted through repeated glacial cycles of the Pleistocene and thus have favoured preferential erosion of the western continental shelf and the creation of large cross-shelf troughs. At the domain scale, the modelled APIS flow-lines (Fig. 1b) are generally consistent with flow directions reconstructed from geological data (Heroy & Anderson Reference Heroy and Anderson2005, Golledge et al. Reference Golledge, Levy, McKay, Fogwill, White, Graham, Smith, Hillenbrand, Licht, Denton, Ackert, Maas and Hall2013). However, locally the model fails to simulate correctly the precise flow pattern of some of the smaller APIS ice streams (e.g. Biscoe Island Ice Stream, Palmer Deep Ice Stream, Gerlache and Boyd Strait Ice Stream; Canals et al. Reference Canals, Urgeles and Calafat2000, Evans et al. Reference Evans, Dowdeswell and Ó Cofaigh2004, Amblas et al. Reference Amblas, Urgeles, Canals, Calafat, Rebesco, Camerlenghi, Estrada, De Batist and Hughes-Clarke2006, Domack et al. Reference Domack, Amblas, Gilbert, Brachfeld, Camerlenghi, Rebesco, Canals and Urgeles2006). This is most probably due to the use of a smoothed topographical grid, which may also impact our ability to correctly predict the finer-scale details of basal erosion. In the central sector of the APIS, geological data suggests that a local ice dome was present over Alexander Island at the LGM (Graham & Smith Reference Graham and Smith2012, Johnson et al. Reference Johnson, Everest, Leat, Golledge, Rood and Stuart2012). Our simulation for the region suggests that the northern part of Alexander Island was indeed independent of (although confluent with) the APIS, but the detail contained in our smoothed topographical input data is insufficient to reproduce the complexity of the discrete glacier systems indicated by offshore data. On the eastern side of the Antarctic Peninsula the modelled ice sheet limits agree more closely with the probable former extent of the LGM ice sheet interpreted from geological evidence (Livingstone et al. Reference Livingstone, Ó Cofaigh, Stokes, Hillenbrand, Vieli and Jamieson2012). However, the model struggles to resolve fine-scale flow features (and therefore areas of potential erosion) such as in the Robertson Trough (Evans et al. Reference Evans, Pudsey, Ó Cofaigh, Morris and Domack2005, Reinardy et al. Reference Reinardy, Larter, Hillenbrand, Murray, Hiemstra and Booth2011). Overall, it is clear that whilst this model may be able to predict the ‘selectivity’ of glacial erosion at a broad scale, fine details of ‘selective linear erosion’ in the APIS are still under-represented.

Although there may be limitations to the accuracy with which our model can mimic the geological record, it does at least allow inferences to be made with respect to the dominant controls on landscape evolution. Subglacial erosion appears to be governed more by the magnitude of horizontal ice flux than by basal thermal regime, thus locations where ice is either thin or slowly-flowing may be protected to some extent, irrespective of whether they are wet-based or not. However, once formed, topographical deeps tend to promote further subglacial erosion in areas where ice is accelerating. This tends to occur where ice flow converges in narrow troughs, since mass conservation requires an increase in velocity to compensate for the reduction in width. Since these topographical conditions remain unchanged during retreat phases of the ice sheet, zones of acceleration are more or less fixed, and it is only the velocity of the ice flowing through these zones that varies. Therefore, this suggests that subglacial erosion will most probably be focused in specific zones throughout a glacial cycle, irrespective of changes in glacier extent, until these areas are no longer covered by grounded ice. In the context of APIS expansions during glacial maxima, our model-based prediction is that subglacial erosion of favourable locations on the outer continental shelf will be episodic, whereas the inner shelf might be exposed to longer periods of ice cover and thus greater erosion. These experiments lend support to the notion of preferential overdeepening within glacial troughs, rather than progressive erosion along the entire length of trough floors during advance/retreat cycles. In this sense, the landscape of the Antarctic Peninsula can truly be considered one of ‘selective’ erosion, and in some areas is both selective and linear.

During retreat of the APIS through the last termination, topographical influences on ice sheet flow were further modified by the effects of rising sea levels and warming oceans. These environmental drivers led to thinning, flotation, and subsequent retreat of grounded ice, with faster flowing outlets responding more quickly than slower flowing ice (Golledge et al. Reference Golledge, Fogwill, Mackintosh and Buckley2012a). On a perfectly flat bed, an ice-stream of uniform width will retreat linearly in response to applied oceanic forcings (Jamieson et al. Reference Jamieson, Vieli, Livingstone, Ó Cofaigh, Stokes, Hillenbrand and Dowdeswell2012, exp. C). However, topographical conditions, such as variability in trough width and bathymetry, lead to a non-linear retreat rate characterized by stillstands at favourable locations (Jamieson et al. Reference Jamieson, Vieli, Livingstone, Ó Cofaigh, Stokes, Hillenbrand and Dowdeswell2012, exp. A). The marine ice sheet instability hypothesis (Weertman Reference Weertman1974, Thomas & Bentley Reference Thomas and Bentley1978) predicts that a retreating marine-based ice sheet will be unconditionally unstable on a bed that slopes landward, assuming no lateral variation in the flow field. Our simulations, in common with those of Jamieson et al. (Reference Jamieson, Vieli, Livingstone, Ó Cofaigh, Stokes, Hillenbrand and Dowdeswell2012), suggest that topographical influences in the Antarctic Peninsula may have allowed outlets, such as the MTIS, to retreat slowly even on reverse slopes, most probably as a consequence of changes in ice-stream geometry that sufficiently modified the rate of ice flux across the grounding line. These results concur with other theoretical studies (Gudmundsson et al. Reference Gudmundsson, Krug, Durand, Favier and Gagliardini2012, Gudmundsson Reference Gudmundsson2013), and highlight the critical influence on retreat rates exerted by topography in deeply incised landscapes like the Antarctic Peninsula.

Conclusions

These simulations have investigated both the role of ice sheet dynamics in modification of subglacial topography, and the role of basal topography in influencing ice sheet behaviour. Using a high-resolution model of the LGM APIS, both at its maximum extent and during stages of retreat, has demonstrated that variability in subglacial erosion potential most probably reflects spatial differences in net horizontal flux, rather than basal temperature. Furthermore, the greatest basal erosion most probably coincides with zones of convergent flow and highest strain rates. During retreat, grounding line migration may be slow even on retrograde slopes if horizontal fluxes are sufficient, but deep basins tend to produce faster retreat, particularly where ice flow is divergent. Together, these results confirm the complex inter-relationship between ice sheets and topography, and provide a mechanistic basis for the palaeo-glaciological interpretation of geological data. Within the limits of model resolution, the simulated pattern of basal erosion is consistent with the geomorphologically-based concept of selective linear erosion, but more detailed topographical input data is required before a comprehensive prediction of subglacial erosion variability may be possible.

Acknowledgements

NRG gratefully acknowledges the helpful suggestions of Bethan Davies, an anonymous reviewer and the Editor, as well as financial support from the Royal Society of New Zealand, VUW Foundation grant ARCCIM and GNS Science.

References

Agassiz, L. 1841. On glaciers, and the evidence of their having once existed in Scotland, Ireland, and England. Proceedings of the Geological Society of London, 3, 327332.Google Scholar
Alley, R.B., Lawson, D.E., Larson, G.J., Evenson, E.B. & Baker, G.S. 2003. Stabilizing feedbacks in glacier bed erosion. Nature, 424, 758760.Google Scholar
Alley, R.B., Anandakrishnan, S., Dupont, T.K., Parizek, B.R. & Pollard, D. 2007. Effect of sedimentation on ice-sheet grounding-line stability. Science, 315, 18381841.Google Scholar
Amblas, D., Urgeles, R., Canals, M., Calafat, A.M., Rebesco, M., Camerlenghi, A., Estrada, F., De Batist, M. & Hughes-Clarke, J.E. 2006. Relationship between continental rise development and palaeo-ice sheet dynamics, northern Antarctic Peninsula Pacific margin. Quaternary Science Reviews, 25, 933944.Google Scholar
Anderson, J.B. & Fretwell, U. Oakes. 2008. Geomorphology of the onset area of a paleo-ice stream, Marguerite Bay, Antarctic Peninsula. Earth Surface Processes and Landforms, 33, 503512.Google Scholar
Arthern, R.J., Winebrenner, D.P. & Vaughan, D.G. 2006. Antarctic snow accumulation mapped using polarization of 4.3-cm wavelength microwave emission. Journal of Geophysical Research - Atmospheres, 111, 10.1029/2004JD005667.CrossRefGoogle Scholar
Atkins, C.B. 2013. Geomorphological evidence of cold-based glacier activity in South Victoria Land, Antarctica. Special Publication of the Geological Society of London, 381, 299318.Google Scholar
Atkins, C.B., Barrett, P.J. & Hicock, S.R. 2002. Cold glaciers erode and deposit: evidence from Allan Hills, Antarctica. Geology, 30, 659662.2.0.CO;2>CrossRefGoogle Scholar
Bougamont, M. & Tulaczyk, S. 2003. Glacial erosion beneath ice streams and ice-stream tributaries: constraints on temporal and spatial distribution of erosion from numerical simulations of a West Antarctic ice stream. Boreas, 32, 178190.Google Scholar
Bougamont, M., Tulaczyk, S. & Joughin, I. 2003. Response of subglacial sediments to basal freeze-on - 2. Application in numerical modeling of the recent stoppage of Ice Stream C, West Antarctica. Journal of Geophysical Research - Solid Earth, 108, 10.1029/2002JB001936.Google Scholar
Briner, J.P., Miller, G.H., Davis, P.T. & Finkel, R.C. 2006. Cosmogenic radionuclides from fiord landscapes support differential erosion by overriding ice sheets. Geological Society of America Bulletin, 118, 406420.Google Scholar
Bueler, E. & Brown, J. 2009. Shallow shelf approximation as a ‘sliding law’ in a thermomechanically coupled ice sheet model. Journal of Geophysical Research - Earth Surface, 114, 10.1029/2008JF001179.Google Scholar
Canals, M., Urgeles, R. & Calafat, A.M. 2000. Deep sea-floor evidence of past ice streams off the Antarctic Peninsula. Geology, 28, 3134.Google Scholar
Cuffey, K.M., Conway, H., Hallet, B., Gades, A.M. & Raymond, C.F. 1999. Interfacial water in polar glaciers and glacier sliding at -17°C. Geophysical Research Letters, 26, 751754.Google Scholar
Davis, P.T., Briner, J.P., Coulthard, R.D., Finkel, R.W. & Miller, G.H. 2006. Preservation of Arctic landscapes overridden by cold-based ice sheets. Quaternary Research, 65, 156163.CrossRefGoogle Scholar
Domack, E., Amblas, D., Gilbert, R., Brachfeld, S., Camerlenghi, A., Rebesco, M., Canals, M. & Urgeles, R. 2006. Subglacial morphology and glacial evolution of the Palmer deep outlet system, Antarctic Peninsula. Geomorphology, 75, 125142.Google Scholar
Dyke, A.S. 1993. Landscapes of cold-centered Late Wisconsinan ice caps, Arctic Canada. Progress in Physical Geography, 17, 223247.Google Scholar
Echelmeyer, K. & Wang, Z.X. 1987. Direct observation of basal sliding and deformation of basal drift at sub-freezing temperatures. Journal of Glaciology, 33, 8398.Google Scholar
Evans, J., Dowdeswell, J.A. & Ó Cofaigh, C. 2004. Late Quaternary submarine bedforms and ice-sheet flow in Gerlache Strait and on the adjacent continental shelf, Antarctic Peninsula. Journal of Quaternary Science, 19, 397407.Google Scholar
Evans, J., Pudsey, C.J., Ó Cofaigh, C., Morris, P. & Domack, E. 2005. Late Quaternary glacial history, flow dynamics and sedimentation along the eastern margin of the Antarctic Peninsula ice sheet. Quaternary Science Reviews, 24, 741774.Google Scholar
Fabel, D., Stroeven, A.P., Harbor, J., Kleman, J., Elmore, D. & Fink, D. 2002. Landscape preservation under Fennoscandian ice sheets determined from in situ produced Be-10 and Al-26. Earth and Planetary Science Letters, 201, 397406.Google Scholar
Fitzsimons, S.J. 2003. Ice-marginal terrestrial landsystems: polar-continental glacier margins. In Evans, D.J.A., ed., Glacial landsystems. London: Arnold, 89110.Google Scholar
Fretwell, P., Pritchard, H.D., Vaughan, D.G. & 57 others. 2013. Bedmap2: improved ice bed, surface and thickness datasets for Antarctica. Cryosphere, 7, 375393.Google Scholar
Golledge, N.R., Fogwill, C.J., Mackintosh, A.N. & Buckley, K.M. 2012a. Dynamics of the last glacial maximum Antarctic ice-sheet and its response to ocean forcing. Proceedings of the National Academy of Sciences of the United States of America, 109, 16 05216 056.CrossRefGoogle ScholarPubMed
Golledge, N.R., Mackintosh, A.N., Anderson, B.M., Buckley, K.M., Doughty, A.M., Barrell, D.J.A., Denton, G.H., Vandergoes, M.J., Andersen, B.G. & Schaefer, J.M. 2012b. Last glacial maximum climate in New Zealand inferred from a modelled Southern Alps icefield. Quaternary Science Reviews, 46, 3045.Google Scholar
Golledge, N.R., Levy, R.H., McKay, R.M., Fogwill, C.J., White, D.A., Graham, A.G.C., Smith, J.A., Hillenbrand, C.D., Licht, K.J., Denton, G.H., Ackert, R.P. Jr, Maas, S.M. & Hall, B.L. 2013. Glaciology and geological signature of the last glacial maximum Antarctic ice sheet. Quaternary Science Reviews, 78, 225247.Google Scholar
Graham, A.G.C. & Smith, J.A. 2012. Palaeoglaciology of the Alexander Island ice cap, western Antarctic Peninsula, reconstructed from marine geophysical and core data. Quaternary Science Reviews, 35, 6381.Google Scholar
Gudmundsson, G.H. 2013. Ice-shelf buttressing and the stability of marine ice sheets. Cryosphere, 7, 647655.Google Scholar
Gudmundsson, G.H., Krug, J., Durand, G., Favier, L. & Gagliardini, O. 2012. The stability of grounding lines on retrograde slopes. Cryosphere, 6, 14971505.CrossRefGoogle Scholar
Haran, T., Bohlander, J., Scambos, T. & Fahnestock, M. 2005. MODIS Mosaic of Antarctica (MoA 2004) image map. Catalogue number 280, digital media. Boulder, CO: National Snow and Ice Data Center.Google Scholar
Heroy, D.C. & Anderson, J.B. 2005. Ice-sheet extent of the Antarctic Peninsula region during the Last Glacial Maximum (LGM) – insights from glacial geomorphology. Geological Society of America Bulletin, 117, 14971512.Google Scholar
Huybrechts, P. 2002. Sea-level changes at the LGM from ice-dynamic reconstructions of the Greenland and Antarctic ice sheets during the glacial cycles. Quaternary Science Reviews, 21, 203231.Google Scholar
Imbrie, J.D. & McIntyre, A. 2006. SPECMAP time scale developed by Imbrie et al. 1984 based on normalized planktonic records (normalized O-18 vs time, specmap.017). 10.1594/PANGAEA.441706.Google Scholar
Jamieson, S.S.R., Sugden, D.E. & Hulton, N.R.J. 2010. The evolution of the subglacial landscape of Antarctica. Earth and Planetary Science Letters, 293, 127.Google Scholar
Jamieson, S.S.R., Hulton, N.R.J., Sugden, D.E., Payne, A.J. & Taylor, J. 2005. Cenozoic landscape evolution of the Lambert basin, East Antarctica: the relative role of rivers and ice sheets. Global and Planetary Change, 45, 3549.Google Scholar
Jamieson, S.R.R., Vieli, A., Livingstone, S.J., Ó Cofaigh, C., Stokes, C., Hillenbrand, C.D. & Dowdeswell, J.A. 2012. Ice-stream stability on a reverse bed slope. Nature Geoscience, 5, 799802.Google Scholar
Johnson, J.S., Everest, J.D., Leat, P.T., Golledge, N.R., Rood, D.H. & Stuart, F.M. 2012. The deglacial history of NW Alexander Island, Antarctica, from surface exposure dating. Quaternary Research, 77, 273280.Google Scholar
Kilfeather, A.A., Ó Cofaigh, C., Lloyd, J.M., Dowdeswell, J.A., Xu, S. & Moreton, S.G. 2011. Ice-stream retreat and ice-shelf history in Marguerite Bay, Antarctic Peninsula: sedimentological and foraminiferal signatures. Geological Society of America Bulletin, 123, 9971015.Google Scholar
Kleman, J. 1994. Preservation of landforms under ice sheets and ice caps. Geomorphology, 9, 1932.Google Scholar
Kleman, J. & Hättestrand, C. 1999. Frozen-bed Fennoscandian and Laurentide ice sheets during the Last Glacial Maximum. Nature, 402, 6366.CrossRefGoogle Scholar
Lenaerts, J.T.M., van den Broeke, M.R., van de Berg, W.J., van Meijgaard, E. & Munneke, P.K. 2012. A new, high-resolution surface mass balance map of Antarctica (1979-2010) based on regional atmospheric climate modeling. Geophysical Research Letters, 39, 10.1029/2011GL050713.Google Scholar
Licht, K.J. & Palmer, E.F. 2013. Glacial erosion and transport by Byrd Glacier, Antarctica during the Last Glacial Maximum. Quaternary Science Reviews, 62, 3248.Google Scholar
Lisiecki, L.E. & Raymo, M.E. 2005. A Pliocene-Pleistocene stack of 57 globally distributed benthic O-18 records. Paleoceanography, 20, 10.1029/2004PA001071.Google Scholar
Livingstone, S.J., Ó Cofaigh, C., Stokes, C.R., Hillenbrand, C.D., Vieli, A. & Jamieson, S.S.R. 2012. Antarctic palaeo-ice streams. Earth-Science Reviews, 111, 90128.Google Scholar
Ó Cofaigh, C., Dowdeswell, J.A. & Pudsey, C.J. 2001. Late Quaternary iceberg rafting along the Antarctic Peninsula continental rise and in the Weddell and Scotia Seas. Quaternary Research, 56, 308321.CrossRefGoogle Scholar
Ó Cofaigh, C., Dowdeswell, J.A., Allen, C.S., Hiemstra, J.F., Pudsey, C.J., Evans, J. & Evans, D.J.A. 2005. Flow dynamics and till genesis associated with a marine-based Antarctic palaeo-ice stream. Quaternary Science Reviews, 24, 709740.Google Scholar
Pattyn, F., Perichon, L., Durand, G. & 25 others. 2013. Grounding-line migration in plan-view marine ice-sheet models: results of the ice2sea MISMIP3d intercomparison. Journal of Glaciology, 59, 410422.Google Scholar
Payne, A.J., Sugden, D.E. & Clapperton, C.M. 1989. Modeling the growth and decay of the Antarctic Peninsula ice sheet. Quaternary Research, 31, 119134.Google Scholar
Petit, J.R., Jouzel, J., Raynaud, D., Barkov, N.I., Barnola, J.M., Basile, I., Bender, M., Chappellaz, J., Davis, M., Delaygue, G., Delmotte, M., Kotlyakov, V.M., Legrand, M., Lipenkov, V.Y., Lorius, C., Pepin, L., Ritz, C., Saltzman, E. & Stievenard, M. 1999. Climate and atmospheric history of the past 420,000 years from the Vostok ice core, Antarctica. Nature, 399, 429436.Google Scholar
Phillips, W.M., Hall, A.M., Mottram, R., Fifield, L.K. & Sugden, D.E. 2006. Cosmogenic 10Be and 26Al exposure ages of tors and erratics, Cairngorm Mountains, Scotland: timescales for the development of a classic landscape of selective linear glacial erosion. Geomorphology, 73, 222245.Google Scholar
Pollard, D. & Deconto, R.M. 2003. Antarctic ice and sediment flux in the Oligocene simulated by a climate-ice sheet-sediment model. Palaeogeography Palaeoclimatology Palaeoecology, 198, 5367.Google Scholar
Pollard, D. & Deconto, R.M. 2009. Modelling West Antarctic ice sheet growth and collapse through the past five million years. Nature, 458, 329332.Google Scholar
Reinardy, B.T.I., Larter, R.D., Hillenbrand, C.D., Murray, T., Hiemstra, J.F. & Booth, A.D. 2011. Streaming flow of an Antarctic Peninsula palaeo-ice stream, both by basal sliding and deformation of substrate. Journal of Glaciology, 57, 596608.Google Scholar
Reinardy, B.T.I., Pudsey, C.J., Hillenbrand, C.D., Murray, T. & Evans, J. 2009. Contrasting sources for glacial and interglacial shelf sediments used to interpret changing ice flow directions in the Larsen Basin, northern Antarctic Peninsula. Marine Geology, 266, 156171.CrossRefGoogle Scholar
Shreve, R. 1984. Glacier sliding at subfreezing temperatures. Journal of Glaciology, 30, 341347.CrossRefGoogle Scholar
Stroeven, A.P., Harbor, J., Fabel, D., Kleman, J., Hättestrand, C., Elmore, D., Fink, D. & Fredin, O. 2006. Slow, patchy landscape evolution in northern Sweden despite repeated ice-sheet glaciation. Geological Society of America Special Papers, 398, 387396.Google Scholar
Sugden, D.E. 1968. The selectivity of glacial erosion in the Cairngorm Mountains, Scotland. Transactions of the Institute of British Geographers, 45, 7992.Google Scholar
Sugden, D.E. 1978. Glacial erosion by the Laurentide ice sheet. Journal of Glaciology, 20, 367391.Google Scholar
Sugden, D.E., Balco, G., Cowdery, S.G., Stone, J.O. & Sass, L.C. 2005. Selective glacial erosion and weathering zones in the coastal mountains of Marie Byrd Land, Antarctica. Geomorphology, 67, 317334.Google Scholar
Thomas, R.H. & Bentley, C.R. 1978. A model for Holocene retreat of the West Antarctic Ice Sheet. Quaternary Research, 10, 150170.Google Scholar
Weertman, J. 1974. Stability of the junction of an ice sheet and an ice shelf. Journal of Glaciology, 13, 311.Google Scholar
Figure 0

Fig. 1 a. Bed topography of the Antarctic Peninsula and surrounding continental shelf, from Fretwell et al. (2013). Thin black lines show modern coast and grounding lines (Haran et al. 2005), dashed black line indicates modelled Last Glacial Maximum (LGM) margin position (Golledge et al.2012a). AI=Alexander Island, BC=Bryan Coast, EIS=Evans Ice Stream, GVIS=George VI Sound, LIS=Larsen Ice Shelf, MB=Marguerite Bay, MT=Marguerite Trough. b. Modelled surface elevation and flow-lines of grounded ice (ice shelves shown in black). c. Modelled horizontal ice flux at the LGM (Golledge et al.2012a). d. Transient grounding line positions during modelled retreat, driven by increasing oceanic temperature and rising sea level

Figure 1

Fig. 2 Relative pattern of subglacial erosion potential (Eq. 1) for a. LGM conditions and b. after ocean-forced retreat. Grey shading denotes areas of the ice sheet where calculated erosion potential is more than an order of magnitude below the lowest coloured value (i.e. <0.01).

Figure 2

Fig. 3 a. Pattern of potential Last Glacial Maximum (LGM) subglacial erosion in the central Antarctic Peninsula. AI=Alexander Island, GVIS=George VI Sound, MB=Marguerite Bay. Present-day coastline and LGM flow lines shown in black. Red line illustrates Marguerite Trough Ice Stream (MTIS) centreline. b. Horizontal strain rates along the MTIS centreline at LGM (bold, green) and during stages of ocean-forced retreat (dashed lines). c. Ice discharge rate (flux) along the MTIS at LGM (bold, red) and during retreat (dashed lines). d. MTIS surface and bed profiles at LGM (bold, blue) and during retreat (dashed lines).

Figure 3

Fig. 4 a. Relationship between calculated subglacial erosion potential and the rate of ice discharge, shaded according to temperature of basal ice relative to the pressure-melting point. b. Thickness of basal water layer in relation to basal ice velocity. c. The distribution of basal ice velocities for cells where the subglacial water layer thickness is less than the minimum shown in b.