Hostname: page-component-cd9895bd7-lnqnp Total loading time: 0 Render date: 2024-12-25T00:57:29.798Z Has data issue: false hasContentIssue false

Antarctic subglacial hydrology: current knowledge and future challenges

Published online by Cambridge University Press:  13 November 2014

David W. Ashmore
Affiliation:
School of Geosciences, University of Aberdeen, Elphinstone Road, Aberdeen AB24 3UF, UK now at: Centre for Glaciology, Institute of Geography and Earth Sciences, Aberystwyth University, Aberystwyth SY23 3DB, UK
Robert G. Bingham*
Affiliation:
School of GeoSciences, University of Edinburgh, Drummond Street, Edinburgh EH8 9XP, UK
*
*corresponding author: [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Flood-carved landforms across the deglaciated terrain of Victoria Land, East Antarctica, provide convincing geomorphological evidence for the existence of subglacial drainage networks beneath the Antarctic ice sheet, and motivate research into the inaccessible environment beneath the contemporary ice sheet. Through this research, our understanding of Antarctic subglacial hydrology is steadily building, and this paper presents an overview of the current state of knowledge. The conceptualization of subglacial hydrological behaviour was developed at temperate and Arctic glaciers, and is thus less mature in the Antarctic. Geophysical and remote sensing observations have demonstrated that many subglacial lakes form part of a highly dynamic network of subglacial drainage beneath the Antarctic ice sheet. Recent research into subglacial water flows, other than those directly concerned with lakes, has discovered potentially significant impacts on ice stream dynamics, ice sheet mass balance, and supplies of water to the ocean potentially affecting circulation and nutrient productivity. Despite considerable advances in understanding there remain a number of grand challenges that must be overcome in order to improve our knowledge of these subglacial hydrological processes.

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

Situated on the current onshore margin of Victoria Land, East Antarctica (c. 161°E, 78°S), is a remarkable deglaciated landscape of channels up to 30 km long, potholes and plunge pools tens of metres deep and up to 70 m across, and areas of stripped and corrugated bedrock ranging in size from 100 m2 to 3 km2 (Fig. 1) that provides convincing evidence for the existence of significant subglacial water flows beneath the Antarctic ice sheet (Sugden et al. Reference Sugden, Denton and Marchant1991, Reference Sugden, Bentley and Ó Cofaigh2006, Sugden & Denton Reference Sugden and Denton2004, Denton & Sugden Reference Denton and Sugden2005, Lewis et al. Reference Lewis, Marchant, Kowalewski, Baldwin and Webb2006, Marchant et al. Reference Marchant, Jamieson and Sugden2011). The size of the constituent landforms is comparable with the famous ‘Channelled Scablands’ landscape of the north-western USA, whose formation has been attributed to rapid flood events resulting from periodic drainage of ice-dammed glacial Lake Missoula during decay of the Pleistocene Laurentide Ice Sheet (Baker & Bunker Reference Baker and Bunker1985). However, the routing of the channels in Victoria Land does not appear to be controlled by simple topographical gradients; rather it is clearly subglacial in origin, as modelled from classical Shreve theory (Shreve Reference Shreve1972, Marchant et al. Reference Marchant, Jamieson and Sugden2011; see Fig. 2 for conceptual diagram). The downstream edges of channel networks are characterized by mega-ripples comprised of cobble-sized boulders, probably formed by the subglacial floodwaters. Dating of these deposits across the region indicates that they are at least 14 m.y.a. (Sugden & Denton Reference Sugden and Denton2004, Margerison et al. Reference Margerison, Phillips, Stuart and Sugden2005); hence, this channelized landscape was carved into the subglacial surface at a time when the East Antarctic Ice Sheet extended well beyond current limits. This labyrinthine landscape of subglacially carved channels stands as a clear monument to the intensity of subglacial water flows beneath the Antarctic ice sheet.

Fig. 1 The ‘Labyrinth’ subglacially-formed, and now deglaciated, channel system in western Wright Valley, Dry Valleys region, East Antarctica. Aerial view to the east. Channels are cut into dolerite. Individual channels are up to 100 m deep. The North Fork of Wright Valley is in the upper left background. Some potholes on the interfluves are littered with dolerite blocks, some of which are imbricated (photograph courtesy David Sugden; caption modified from Denton & Sugden Reference Denton and Sugden2005).

Fig. 2 Conceptual diagram of the typical situation of subglacial lakes and configuration of water flows beneath the Antarctic ice sheet.

Therefore, it is perhaps surprising that, until the last decade, water flows beneath the Antarctic ice sheet have received little attention in the scientific literature. However, over the last decade several developments have transformed our understanding of subglacial water flows beneath the Antarctic ice sheet. These include: i) a growing realization of the significance of subglacial water flows to continental-scale ice dynamics (e.g. Siegert & Bamber Reference Siegert and Bamber2000, Pattyn et al. Reference Pattyn, De Smedt and Souchez2004, Fricker & Scambos Reference Fricker and Scambos2009), oceanic circulation (e.g. Evatt et al. Reference Evatt, Fowler, Clark and Hulton2006, Payne et al. Reference Payne, Holland, Shepherd, Rutt, Jenkins and Joughin2007) and nutrient productivity (e.g. Statham et al. Reference Statham, Skidmore and Tranter2008, Skidmore Reference Skidmore2011), ii) the development of remote sensing techniques that facilitate recovery or inference of subglacial conditions beneath the contemporary ice sheet (e.g. Robin et al. Reference Robin, Drewry and Meldrum1977, Blankenship et al. Reference Blankenship, Bentley, Rooney and Alley1986, Smith Reference Smith1997a), iii) enhanced imaging of subglacial hydraulic networks across continental shelf regions previously covered by the expanded ice sheet (e.g. Nitsche et al. Reference Nitsche, Gohl, Larter, Hillenbrand, Kuhn, Smith, Jacobs, Anderson and Jakobsson2013), and iv) the constant refinement of glaciohydrological theories from other field sites, notably in Greenland (e.g. Zwally et al. Reference Zwally, Abdalati, Herring, Larson, Saba and Steffen2002, Tedstone et al. Reference Tedstone, Nienow, Sole, Mair, Cowton, Bartholomew and King2013).

The aim of this paper is to provide a brief overview of the current state of knowledge of subglacial hydrology across Antarctica, beginning by placing into context how knowledge of subglacial hydrology has grown from earlier studies mostly of alpine glaciers but more recently of those in the Arctic. This is followed by a discussion of where most hydrological attention in Antarctica has been focused until recently, namely the identification and exploration of subglacial lakes, before moving on to discuss examples of our burgeoning understanding of dynamic flows of water beneath the ice sheet. While many recent advances in understanding have been made, there remains much to be understood about the ways in which water is generated, stored, flows beneath and leaves the Antarctic ice sheet, and we therefore attempt to identify some of the grand challenges for improving our understanding of Antarctic subglacial hydrology. Figure 3 is provided as a reference guide for the Antarctic features and locations discussed.

Fig. 3 Antarctic locations referred to in the text, using the ice-surface velocity map of Rignot et al. (Reference Rignot, Mouginot and Scheuchl2011), superimposed over the MODIS Mosaic of Antarctica as a basemap. The locations of subglacial lakes are denoted by circles, and the subglacial-flood landforms shown in Fig. 1 are located by the black star. An inventory of all known subglacial lake locations in Antarctica is provided by Wright & Siegert (Reference Wright and Siegert2012). AB=Aurora Basin, AL=Adventure Lakes, BG=Byrd Glacier, BIS=Bindschadler Ice Stream, DA=Dome A, DC=Dome C, DF=Dome F, EAIS=East Antarctic Ice Sheet, EIR=Engelhardt Ice Ridge, EIS=Evans Ice Stream, GSM=Gamburtsev Subglacial Mountains, IIS=Institute Ice Stream, KIS=Kamb Ice Stream, LD=Law Dome, MAIS=MacAyeal Ice Stream, MIS=Mercer Ice Stream, PIG=Pine Island Glacier, RBIS=Roi Baudouin Ice Shelf, RG=Ragnhild Glaciers, RIR=Raymond Ice Ridge, RIS=Rutford Ice Stream, RL=Recovery Lakes, SC=Soya Coast, SD=Siple Dome, SG=Slessor Glacier, SLE=Subglacial Lake Ellsworth, SLV=Subglacial Lake Vostok, SLW=Subglacial Lake Whillans, TD=Taylor Dome, ThwG=Thwaites Glacier, TotG=Totten Glacier, VL=Victoria Land, WAIS=West Antarctic Ice Sheet, WB=Wilkes Basin, WD=WAIS divide, WIS=Whillans Ice Stream, WL=Wilkes Land.

Context

Scientists have been studying glacier hydrology for well over 40 years (for detailed reviews see Hubbard & Nienow Reference Hubbard and Nienow1997, Fountain & Walder Reference Fountain and Walder1998, Cuffey & Paterson Reference Cuffey and Paterson2010). Important concepts from these studies include: i) glacial meltwater can be generated supraglacially, englacially and subglacially from various sources, ii) meltwater follows different flowpaths through glaciers (Cuffey & Paterson Reference Cuffey and Paterson2010), iii) flowpaths can evolve in form with consequent impacts on the efficiency of water routing (Shreve Reference Shreve1972, Nienow et al. Reference Nienow, Sharp and Willis1998), and iv) the form and efficiency of the subglacial drainage system exerts a significant impact on the motion of the overlying ice flow (Iken & Bindschadler Reference Iken and Bindschadler1986, Mair et al. Reference Mair, Nienow, Sharp, Wohlleben and Willis2002). These concepts all hold for temperate glaciers, through which water flow is unrestricted by thermal considerations. For many years, the study of water flow through polythermal glaciers remained relatively unpursued, due in part to the conventional assumption that large proportions of cold ice would act to limit significant water flows, thereby preventing significant subglacial drainage system evolution and any hydraulic instabilities that might exert significant impacts on ice motion. Work by Müller & Iken (Reference Müller and Iken1973) on White Glacier, Arctic Canada, contradicted this assumption at an early stage, but it was not until a series of field studies on Arctic polythermal glaciers during the 1980s and 1990s that it became more readily accepted that drainage systems at polythermal glaciers do evolve, and that this can have readily observable impacts on patterns of ice flow (e.g. Hock & Hooke Reference Hock and Hooke1993, Bingham et al. Reference Bingham, Hubbard, Nienow and Sharp2008). Translation and upscaling of these concepts to various locations on the Greenland ice sheet has brought the issue to global attention (Zwally et al. Reference Zwally, Abdalati, Herring, Larson, Saba and Steffen2002, Van de Wal et al. Reference Van de Wal, Boot, van den Broeke, Smeets, Reijmer, Donker and Oerlemans2008, Bartholomew et al. Reference Bartholomew, Nienow, Mair, Hubbard, King and Sole2010, Sundal et al. Reference Sundal, Shepherd, Nienow, Hanna, Palmer and Huybrechts2011, Tedstone et al. Reference Tedstone, Nienow, Sole, Mair, Cowton, Bartholomew and King2013), and shown the significance of hydrological processes for ice dynamics at the ice-sheet-scale (e.g. Price et al. Reference Price, Payne, Catania and Neumann2008, Shannon et al. Reference Shannon, Payne and Bartholomew2013).

Antarctica continues to present a distinct glaciohydrological context. Under current climatic conditions the 0°C isotherm is rarely reached anywhere across West or East Antarctica, hence surface melt is limited to non-existent, and supraglacially-forced processes, which are considered to be responsible for inducing ice dynamic feedbacks in Arctic polythermal glaciers, cannot occur. A caveat to this is presented by the warmer, northward-trending Antarctic Peninsula region, in which it is conceivable that supraglacially-forced englacial connections could be established, thereby inducing polythermal-glacier drainage-system evolution and dynamic effects similar to those observed in the Arctic. Although this process has not been observed directly on Antarctic Peninsula polythermal glaciers, indirect evidence for its feasibility is provided by the demonstrable establishment of supraglacial-subglacial water connections on fringing ice shelves, which occasionally significantly impacts ice shelf stability and the glaciers formerly buttressed by them (Glasser & Scambos Reference Glasser and Scambos2008). However, for the Antarctic Peninsula glaciers overall, even though supraglacial-subglacial connections might occur, it is probable that their significance in any form of ice dynamic response mediation (cf. Hulbe et al. Reference Hulbe, Scambos, Youngberg and Lamb2008) is far outweighed by their collective and dramatic response to oceanic forcing along the coastline (Pritchard et al. Reference Pritchard, Arthern, Vaughan and Edwards2009).

This paper will not discuss the Antarctic Peninsula region further and will focus on the West and East Antarctic ice sheets, which comprise the vast majority of ice cover across the continent, and for which the subglacial hydrology remains only tentatively understood. A conceptual diagram for the following discussion is provided in Fig. 2.

Subglacial lakes

Beneath the contemporary continental ice sheets of Antarctica the identification and interrogation of subglacial hydrological phenomena is dependent upon multiple remote sensing techniques. In the late 1960s, scientists using airborne radar to survey ice thickness across the continent reported very clear, unusually strong and flat basal reflectors at many localities, which they interpreted as distinct bodies of collected subglacial water, or ‘subglacial lakes’ (Robin et al. Reference Robin, Drewry and Meldrum1977). Subglacial lakes are found wherever sufficient water is generated at the base of the ice sheet and gathers into depressions in hydraulic potential (Dowdeswell & Siegert Reference Dowdeswell and Siegert2003) and where inflow at least equals, if not exceeds, outflow. For several decades, the study of Antarctic subglacial hydrology has been synonymous with the identification of subglacial lakes, and elucidation of their formation and behaviour. This is because they are clearly identified in radio echo sounding (RES) data (e.g. Robin et al. Reference Robin, Drewry and Meldrum1977, and Fig. 4) and their significance is manifold, for example in their capacity to support life or impact on overlying ice dynamics (e.g. Siegert et al. Reference Siegert, Kennicutt II and Bindschadler2011). Successive inventories of Antarctic subglacial lakes have been published; initially using only the clearest lake-like returns visible in RES data but progressively incorporating ancillary forms of satellite observations (e.g. Fricker et al. Reference Fricker, Scambos, Bindschadler and Padman2007, Wright & Siegert Reference Wright and Siegert2012) and multiple-attribute processing of new digital radar data (e.g. Carter et al. Reference Carter, Blankenship, Peters, Young, Holt and Morse2007). The most recent inventory provides the locations of 379 subglacial lakes (Wright & Siegert Reference Wright and Siegert2012). The largest lakes are clearly expressed by depressions in the ice surface (e.g. Ridley et al. Reference Ridley, Cudlip and Laxon1993), which has been mapped from satellite observations across the continent (Bamber et al. Reference Bamber, Gomez-Dans and Griggs2009). It is therefore probable that all of the most substantial subglacial lakes across Antarctica have now been identified. However, even the basic dimensions of most of the lakes are not known, i.e. depth and volume, and there are undoubtedly many smaller lakes beneath the ice cover, which will continue to be discovered as RES surveys continue to explore the subglacial environment (Wright & Siegert Reference Wright and Siegert2012). Recent work by Livingstone et al. (Reference Livingstone, Clark, Woodward and Kingslake2013) offers potential in efforts to pinpoint the locations of smaller lakes where knowledge of the bed is good.

Fig. 4 Radargrams of the West Antarctic subglacial hydrological environment. a. Subglacial highlands near the West Antarctic divide showing steep, complex topography and well-preserved internal layers; note the bright reflection 27 km along-track indicating pooled water. b. The margin of Evans Ice Stream demonstrating the contrast between the ice stream, characterized by a bright reflection and absent-layering (left) and dimmer reflection and well-preserved layering in the slow-moving area (right). c. Flat and bright reflectors at the base of subglacial valleys; note their non-specular nature indicating the presence of saturated sediment, rather than a ‘definite lake’ (cf. Carter et al. Reference Carter, Blankenship, Peters, Young, Holt and Morse2007).

Before the last decade, most research on subglacial lakes explicitly or implicitly treated them as isolated, relatively stable, ‘closed-system’ phenomena. This led many to conceive of subglacial lakes as potential refugia, isolated and unique from elsewhere on Earth for millions of years (e.g. Priscu et al. Reference Priscu, Adams, Lyons, Voytek, Mogk, Brown, McKay, Takacs, Welch, Wolf, Kirshtein and Avci1999). This arresting notion motivated several high profile efforts to sample subglacial lake environments directly over recent years. Direct sampling was also driven by the potential of the lake bottom sediment profiles to record the overlying ice history (Bentley et al. Reference Bentley, Christoffersen, Hodgson, Smith, Tulaczyk and Le Brocq2011). Scientific drilling projects at the subglacial lake sites of Vostok and Ellsworth were particularly motivated by the search for subglacial life. Lake Vostok, East Antarctica, is the continent’s largest known subglacial lake with an estimated volume of 5400 km3 (Studinger et al. Reference Studinger, Bell and Tikku2004). It contains water that actively circulates and accretes onto the underside of the ice sheet at its southern end (Siegert et al. Reference Siegert, Kwok, Mayer and Hubbard2000, Bell et al. Reference Bell, Studinger, Tikku, Clarke, Gutner and Meertens2002), and preliminary samples of the accreted ice have provided evidence for the presence of microorganisms in the lake (Shtarkman et al. Reference Shtarkman, Kocer, Edgar, Veerapaneni, D’elia, Morris and Rogers2013). Lake Ellsworth fills an overdeepened former fjord flanking the Ellsworth Mountains in West Antarctica, which contains 1.37 km3 of water (Woodward et al. Reference Woodward, Smith, Ross, Thoma, Corr, King, King, Grosfeld, Tranter and Siegert2010). During 2012–13, another subglacial lake, Lake Whillans, West Antarctica, was the subject of scientific drilling investigations. Lake Whillans covers a c. 60 km2 region beneath Whillans Ice Stream and is a much shallower feature, probably only c. 2 m deep across much of its extent (Christianson et al. Reference Christianson, Jacobel, Horgan, Anandakrishnan and Alley2012, Horgan et al. Reference Horgan, Anandakrishnan, Jacobel, Christianson, Alley, Heeszel, Picotti and Walter2012). Although Lake Whillans may harbour life and access to the subglacial sediments may provide information on the ice-flow history (Fricker et al. Reference Fricker, Powell and Priscu2011), the initial discovery in 2007 by satellite altimetry, exposing it as a site of distinct cyclical ice-surface rise and fall (Fricker et al. Reference Fricker, Scambos, Bindschadler and Padman2007), pointed to strong dynamism in the subglacial hydraulic environment, motivating further investigation.

Over the last decade, a significant body of evidence has accumulated to demonstrate that many subglacial lakes form part of an interconnected network, draining up-gradient locations to down-gradient locations and ultimately to the ice sheet margin. This hypothesis was established by Dowdeswell & Siegert (Reference Dowdeswell and Siegert2003), but the first observational confirmation of its veracity was provided by Spikes et al. (Reference Spikes, Csatho, Hamilton and Whillans2003) and Gray et al. (Reference Gray, Joughin, Tulaczyk, Spikes, Bindschadler and Jezek2005), who interpreted satellite signals of isolated ice surface elevation change in the Siple Coast region of West Antarctica as the expressions of episodic drainage/fill events in connected subglacial lakes. Subsequently, Wingham et al. (Reference Wingham, Siegert, Shepherd and Muir2006) used radar altimetry to record movement between pairs of subglacial lakes over tens of km in East Antarctica. Fricker et al. (Reference Fricker, Scambos, Bindschadler and Padman2007) and Fricker & Scambos (Reference Fricker and Scambos2009) utilized satellite laser altimetry to record pervasive, connected subglacial lake activity across lower Mercer and Whillans ice streams in West Antarctica. Smith et al. (Reference Smith, Fricker, Joughin and Tulaczyk2009) collated all satellite laser altimeter observations of vertical ice surface change across Antarctica between 2003 and 2008 that could conceivably reflect subglacial lake drainage/filling events to produce an inventory of 124 ‘active’ subglacial lakes across the Antarctic ice sheet. These observations strongly suggest that the treatment of subglacial lakes as isolated, closed systems is inherently flawed, and that it is more appropriate to consider each lake as part of an open system. Recent RES surveys of some of the ‘active’ lake sites that do not show the classic lake-like reflectors support this view, suggesting that at those sites the lakes may periodically experience wholesale drainage or that they are very shallow. An alternative explanation is that the surface movement detected by altimetry is not a signal of lake drainage/filling but rather the surface expression of subglacial migration of packets of basal water or sediment flows facilitated by changes to subglacial hydrological routing (Wright & Siegert Reference Wright and Siegert2012, Siegert et al. Reference Siegert, Ross, Corr, Smith, Jordan, Bingham, Ferraccioli, Rippin and Le Brocq2014). This interpretation implies that in some areas the storage of water and sediment is relatively temporary, and driven by internal hydrological (re)organization; consequently, caution should be applied when interpreting surface uplift/subsidence as the location of a fixed ‘lake’ that drains and recharges with some periodicity. Either explanation for the mismatch appeals to considerable dynamism in the subglacial hydrological system.

The impact of subglacial lakes on vertical ice motion, in some cases through several km of ice, highlights their potentially pervasive influence on ice dynamics. Siegert & Bamber (Reference Siegert and Bamber2000), Pattyn et al. (Reference Pattyn, De Smedt and Souchez2004), Bell et al. (Reference Bell, Studinger, Shuman, Fahnestock and Joughin2007) and Peters et al. (Reference Peters, Blankenship, Carter, Kempf, Young and Holt2007) have all noted that subglacial lakes towards the ice sheet interiors coincide with ice stream onset regions and may, therefore, play a critical role in defining the configuration of drainage across Antarctica. This is particularly true in areas of East Antarctica where thick inland ice causes large areas of the bed to be at pressure melting point, allowing liquid water to collect in hydraulic potential lows caused by low ice surface slopes and rough subglacial topography. Of further significance, Stearns et al. (Reference Stearns, Smith and Hamilton2008) linked a 14-month acceleration of Byrd Glacier, East Antarctica, to the drainage of two subglacial lakes c. 200 km further upstream. To explain the acceleration (and subsequent deceleration) of this glacier, Stearns et al. (Reference Stearns, Smith and Hamilton2008) drew directly on established relationships between subglacial hydrological configurations and ice dynamics of temperate glaciers developed by Kamb (Reference Kamb1987). These papers have been especially important in underscoring that: i) subglacial water clearly has the capacity to travel long distances through drainage networks beneath the Antarctic ice sheet, and ii) it is the flow of subglacial water from one place to another, especially if there are sudden changes in volume, that may have the most profound influence on ice dynamics. The latter point is profoundly familiar to researchers with a background in temperate and Arctic polythermal glaciers and, more recently, the Greenland ice sheet, although in these cases the most variable and glaciodynamically significant water flows tend to be induced by surface melt penetrating to the bed, whereas in Antarctica alternative forcing mechanisms should be considered. Periodic subglacial lake drainage provides one such mechanism (Evatt et al. Reference Evatt, Fowler, Clark and Hulton2006, Pattyn Reference Pattyn2011).

Subglacial water away from lakes

This section will focus on observations and theories of subglacial water generation and flow beneath the Antarctic ice sheet, separate from the explicit study of subglacial lakes. A seminal programme of studies on the Siple Coast ice streams, initiated in the 1980s, provided some of the earliest observational groundwork for the existence of distributed water at the beds of ice streams and their tributaries. Using seismic techniques, Blankenship et al. (Reference Blankenship, Bentley, Rooney and Alley1986) presented the first evidence to show that the bed of an active ice stream, in this case Whillans Ice Stream, was composed of water-saturated sediments. Alley et al. (Reference Alley, Blankenship, Rooney and Bentley1989) demonstrated the crucial importance of this water in facilitating deformation of the underlying sediments and therefore fast flow in the overlying ice. Drilling to the bed of this ice stream, Engelhardt et al. (Reference Engelhardt, Humphrey, Kamb and Fahnestock1990) confirmed that the bed was at pressure melting point and that the subglacial water was highly pressurized. Subsequent experiments demonstrated that the subglacial water pressures (hence, inferred water flows) were highly variable (Engelhardt & Kamb Reference Engelhardt and Kamb1997). Part of the variability could be attributed to tidal influences at sites sufficiently proximal to the grounding line; but there was also considerable unexplained variability in water pressure, which, they argued, acted cumulatively to support continued fast flow of overlying ice. Parallel studies by Smith (Reference Smith1997a, Reference Smith1997b) and Vaughan et al. (Reference Vaughan, Smith, Nath and Le Meur2003) also derived seismic acoustic-impedance to argue for the existence of wet sediments beneath several additional West Antarctic ice streams, while King et al. (Reference King, Woodward and Smith2004) presented seismic evidence that water may be routed through small channels, or ‘canals’, along the Rutford Ice Stream bed. All of these studies, and further analysis of RES bed reflectivity, have shown that most ice streams, and many ice stream tributaries, are underlain by ice at pressure melting point, contrasting with surrounding regions commonly underlain by cold-based ice. Therefore, the presence of water is crucial to ice dynamics in many areas and for determining the current configuration of ice flow across Antarctica. However, the mechanisms by which the water is generated, and the specific processes by which it flows and impacts upon overlying ice dynamics, remain poorly understood. For example, the presence of water at the bed alone is not exclusively responsible for the fast flow of ice, as verified by the existence of water beneath the currently stagnated Kamb Ice Stream (Catania et al. Reference Catania, Conway, Gades, Raymond and Engelhardt2003). Moreover, the fast flow of the tributaries of Slessor Glacier, East Antarctica, appears to be initiated by ice deformation alone (Rippin et al. Reference Rippin, Bamber, Siegert, Vaughan and Corr2003), with subglacial water only becoming available farther downstream, presumably when frictional heat sources sufficiently elevate basal temperatures.

With supraglacial and englacial meltwater sources ruled out, sources of basal water beneath the Antarctic ice sheet must be derived predominantly from geothermal heating and pressure melting. Additional contributions may come from: i) frictional heating generated by ice motion over the subglacial substrate, ii) occasional release of water through the regelation process (Weertman Reference Weertman1957), and iii) (at a local level) drainage from subglacial lakes or reservoirs upstream. However, the distribution of geothermal heating beneath Antarctica is notoriously poorly constrained due to a dearth of observations. In the last decade, two modelled distributions of geothermal heat flux across the Antarctic bed have been derived: the first extrapolated from a global seismic model of the Earth’s crust and upper mantle (Shapiro & Ritzwoller Reference Shapiro and Ritzwoller2004) and the second derived from satellite magnetic measurements (Maule et al. Reference Maule, Purucker, Olsen and Mosegaard2005). Both have been used in ice sheet modelling to derive continent-wide maps of basal thermal conditions (Pattyn Reference Pattyn2010, Van Liefferinge & Pattyn Reference Van Liefferinge and Pattyn2013) but they differ in many details, rendering significant uncertainty to any interpretations of subglacial water distribution. At a broad level, both models show much greater geothermal heat flux across West Antarctica relative to East Antarctica, supporting (though not confirming) claims of active volcanism beneath the West Antarctic Ice Sheet (Blankenship et al. Reference Blankenship, Bell, Hodge, Brozena, Behrendt and Finn1993). Brief periods of volcanic activity may be responsible for producing surplus meltwater sufficient to induce excess basal slip in some localities (Vogel & Tulaczyk Reference Vogel and Tulaczyk2006, Corr & Vaughan Reference Corr and Vaughan2008), in effect aping the transient lake-drainage-triggered acceleration of Byrd Glacier reported by Stearns et al. (Reference Stearns, Smith and Hamilton2008). The importance of active volcanism to the overall pattern of ice dynamics in Antarctica remains debated.

To expand upon observational records of the distribution and processes of water flow beneath the Antarctic ice sheet, several teams from the 1980s onwards examined the properties of bed returns in RES data for signals of water and its variations, i.e. other than identifying just the obvious lake-like reflectors. Shabtaie et al. (Reference Shabtaie, Whillans and Bentley1987) argued that relative reflection amplitudes, after corrections for variations in ice thickness and taking into account possible variations in subglacial geology, varied inversely with freezing at the bed. Bentley et al. (Reference Bentley, Lord and Liu1998) later applied a revised version of this scheme to suggest high bed reflection amplitudes beneath Kamb Ice Stream evinced liquid water at its base, while low relative reflection amplitudes beneath neighbouring Engelhardt Ice Ridge were indicative of frozen till. Gades (Reference Gades1998) drew on these studies, and from radar work on temperate glaciers, to develop a range of ‘bed reflection powers’ for subglacial materials from frozen permafrost to liquid water, then applied this classification to the subglacial interface sounded across Siple Dome (Gades et al. Reference Gades, Raymond, Conway and Jacobel2000). This study showed that while the dome was frozen to the bed, the ice streams flanking it were underlain by water-saturated material. Subsequent RES surveying and recovery of bed reflection power (as quantified by the amplitudes of the bed-return waves) across a number of the Siple Coast ice streams, calibrated with observations of water content in nearby boreholes, confirmed the contention that the ice streams (including the currently stagnant Kamb Ice Stream) are underlain by wet sediment, while in the intervening ridges the water is frozen to the bed (Catania et al. Reference Catania, Conway, Gades, Raymond and Engelhardt2003, Peters et al. Reference Peters, Blankenship and Morse2005).

In recent years, the use of RES to search for water beneath the Antarctic ice sheet has been adopted as a standard part of any survey, and has been applied far beyond the Siple Coast region, into other parts of West Antarctica and across East Antarctica. Table I provides a summary of surveys and significant findings (see also example RES data presented in Fig. 4). In acquiring and analysing more recent data and, in some cases, retrospectively analysing older surveys, research has advanced from the simple binary exercise of distinguishing between ‘dry’ and ‘wet’ beds, and significant developments have been made. Firstly, now that modern RES systems are fully digitized, bed returns can be acquired at much higher resolution and the collected data analysed with much greater efficiency. Though data are always degraded by beam spreading, limiting our ability to acquire data at the resolution of many hypothesized subglacial system structures, the recovery of hydrological variability at finer resolution is much improved. Technical advances in data acquisition, such as synthetic aperture processing radio echo sounding platforms, have aided this development (Helière et al. Reference Helière, Lin, Corr and Vaughan2007, Peters et al. Reference Peters, Anandakrishnan, Alley and Smith2007). Synthetic aperture processing, used together with migration processing (inherited from seismic processing), reinstates energy to its true position in two- or three-dimensions, thereby increasing resolution. Secondly, the treatment of englacial attenuation, the loss of signal on its passage through the ice, has seen progress recently. Matsuoka (Reference Matsuoka2011) highlighted the risks of over-interpreting bed returns in the absence of correct treatment of englacial attenuation, especially where the ice-flow regime and subglacial topography are complex (see Matsuoka et al. Reference Matsuoka, MacGregor and Pattyn2010 for a review). Thirdly, information in the bed returns other than, or supplementary to, the amplitude of the bed return is being used. For example, Murray et al. (Reference Murray, Corr, Forieri and Smith2008) used coincident radar and seismic profiles to recover subglacial conditions, while Schroeder et al. (Reference Schroeder, Blankenship and Young2013) used specular anisotropy of bed returns to image sub-resolution hydrological features largely independently of the effects of englacial attenuation.

Table I Summary of radioglaciological studies in which bed-reflection power (bed reflectivity) has been acquired across parts of the Antarctic ice sheet organized chronologically by survey date. Traverses between locations are denoted by hyphenation. Only Antarctic-focused studies from the last 15 years specifically concerned with the basal reflectivity of grounded ice are listed. Bright reflections have been used to (semi-)qualitatively delineate subglacial lakes since the 1960s and such studies are not included here.

BRP=bed-returned power, DMLWasa=Dronning Maud Land Wasa expedition, EAIS=East Antarctic Ice Sheet, EPICA=European Project for Ice Coring in Antarctica, KIS=Kamb Ice Stream, MSGL=mega-scale glacial lineations.

Several researchers have sought to model flow routes beneath the ice sheet to develop the theory that water flows for great distances beneath the Antarctic ice sheet. Rémy & Legrésy (Reference Rémy and Legrésy2005) performed hydrological network analysis on high-resolution ice surface data over Wilkes Land, East Antarctica, mapping an inferred subglacial network that linked several known subglacial lakes. A significant assumption in their analysis was that surface topography on a broad-scale reflects the subglacial topography; though later work demonstrated that this only holds true under certain conditions (De Rydt et al. Reference De Rydt, Gudmundsson, Corr and Christoffersen2013). Siegert et al. (Reference Siegert, Le Brocq and Payne2007) modelled subglacial water routing across Antarctica using hydropotential methodology (Shreve Reference Shreve1972), which requires knowledge of the ice surface and the bed. Le Brocq et al. (Reference Le Brocq, Payne, Siegert and Alley2009) used a similar method when developing a subglacial water flow component for ice sheet modelling. The results of these exercises must be viewed with a confidence relative to our knowledge of bed topography and conditions across different regions, and in the context that small changes to the ice surface, such as external forcings or internal instabilities, can exert significant influences on subglacial water flowpaths (Wright et al. Reference Wright, Siegert, Le Brocq and Gore2008). Carter et al. (Reference Carter, Blankenship, Young, Peters, Holt and Siegert2009b) modelled the probable flow mechanism and impact on ice mass budget of the Adventure Lakes drainage event (described by Wingham et al. Reference Wingham, Siegert, Shepherd and Muir2006). The authors suggested that the water flow was probably distributed along a broad, shallow water system, perhaps through basal sediments, and that this flowpath delayed the arrival of water to downstream points by approximately 12 months. Carter & Fricker (Reference Carter and Fricker2012) modelled the subglacial water flows to the Siple Coast. The aforementioned studies have all assumed, or inferred, that most subglacial water flows through distributed drainage systems beneath the ice sheet. However, Le Brocq et al. (Reference Le Brocq, Ross, Griggs, Bingham, Corr, Ferraccioli, Jenkins, Jordan, Payne, Rippin and Siegert2013) observed supraglacial channels close to the grounding line on the surfaces of a number of ice shelves, and inferred that they may originate from concentrated outflows of subglacial water flowing along channelized flowpaths beneath the inland ice. Should this be true, and further data are required as confirmation, it challenges the way in which subglacial flows have been modelled. In support of this, Schroeder et al. (Reference Schroeder, Blankenship and Young2013) demonstrated that, beneath Thwaites Glacier, the specularity of radar returns changed with respect to whether flightlines were parallel or perpendicular to ice flow, indicating the presence of distributed ‘canals’ and upward incising channels in the upstream and downstream parts of the bed, respectively.

Extensive surveys over parts of East Antarctica are proffering further insight into subglacial water routing. For example, Wright et al. (Reference Wright, Young, Roberts, Schroeder, Bamber, Dowdeswell, Young, Le Brocq, Warner, Payne, Blankenship, van Ommen and Siegert2012) presented a suite of evidence from an aerogeophysical survey over the 287 000 km3 Aurora Basin to demonstrate that subglacial lakes near the Dome C ice divide probably discharge through Aurora Basin to the coast via Totten Glacier. A survey of the Gamburtsev Subglacial Mountains in East Antarctica has also provided a glimpse of the subglacial hydrological network in the deep interior (Wolovick et al. Reference Wolovick, Bell, Creyts and Frearson2013). Water is predominantly routed along a system of alpine overdeepenings created during the early growth phase of the East Antarctic Ice Sheet, and the drainage networks follow valley floors either uphill or downhill depending on the gradient of the ice sheet surface. Where the water is forced uphill along the valley floor by the ice surface gradient, it terminates in or near distinct and sometimes very large (up to 25% of the ice column) plumes of refrozen basal ice which have strong potential to alter basal ice rheology and fabric, and are implicated in thickening the overlying ice column (Bell et al. Reference Bell, Ferraccioli, Creyts, Braaten, Corr, Das, Damaske, Frearson, Jordan, Rose, Studinger and Wolovick2011). These observations suggest that supercooling of basal water remains a significant, and perhaps underestimated, component of the subglacial water budget across Antarctica, by acting to recover water that would otherwise eventually drain to the margins.

Despite improved knowledge of the Antarctic subglacial hydrology, there remain few observations targeted towards monitoring changes in the subglacial hydrological system. The ‘active’ lake studies drew attention to the instability of subglacial water sources and flows (e.g. Gray et al. Reference Gray, Joughin, Tulaczyk, Spikes, Bindschadler and Jezek2005, Wingham et al. Reference Wingham, Siegert, Shepherd and Muir2006, Fricker et al. Reference Fricker, Scambos, Bindschadler and Padman2007), but the majority of evidence is provided indirectly by glaciodynamic instabilities that are probably associated with unstable water flows in the subglacial drainage system. A clear example of a glaciodynamic instability probably related to changes in subglacial water flow is provided by Kamb Ice Stream. Formerly fast-flowing like the other Siple Coast ice streams, it switched to a slow flow state more than a century ago (Retzlaff & Bentley Reference Retzlaff and Bentley1993). Anandakrishnan & Alley (Reference Anandakrishnan and Alley1997) surmised that the stagnation of flow resulted from piracy of much of the ‘lubricating’ subglacial water to neighbouring Whillans Ice Stream, allowing localized ‘sticky spots’ to gain eminence sufficient to deactivate fast flow. Catania et al. (Reference Catania, Scambos, Conway and Raymond2006) presented further evidence that around the same time the margin of Kamb Ice Stream shifted inwards, resulting in a narrowing of the ice stream trunk and discharge capacity by c. 30%. Other authors have shown that with lower water fluxes much of the remaining water has been susceptible to basal freeze-on (Christoffersen & Tulaczyk Reference Christoffersen and Tulaczyk2003, Vogel et al. Reference Vogel, Tulaczyk, Kamb, Englehardt, Carsey, Behar, Lane and Joughin2005). Examination of sediments recovered from beneath Kamb Ice Stream (Engelhardt & Kamb Reference Engelhardt and Kamb2013), ancillary evidence from ice surface flow-lines extending across the ice shelf (Hulbe & Fahnestock Reference Hulbe and Fahnestock2007) and modelling (Christoffersen et al. Reference Christoffersen, Tulaczyk and Behar2010, Catania et al. Reference Catania, Hulbe, Conway, Scambos and Raymond2012, Van der Wel et al. Reference Van der Wel, Christofferson and Bougamont2013) suggest that over long timescales Kamb Ice Stream may undergo cycles of activity and stagnation; the cause of the initial piracy or recovery of water flows beneath the ice stream remains enigmatic. Evidence of ice stream stagnation probably due to water piracy has also been reported from Carlson Inlet/Rutford Ice Stream (Vaughan et al. Reference Vaughan, Corr, Smith, Pritchard and Shepherd2008) and in the Ragnhild Glacier system of East Antarctica (Pattyn et al. Reference Pattyn, De Brabander and Huyghe2005).

Seismic techniques have been successfully deployed to observe changes in the subglacial hydrological system beneath Antarctica. For example, repeat active-seismic surveys on Rutford Ice Stream have shown switches in hydrological behaviour at the same site surveyed at six/seven year intervals (Smith et al. Reference Smith, Murray, Nicholls, Makinson, Adalgeirsdóttir, Behar and Vaughan2007). In another study, Winberry et al. (Reference Winberry, Anandakrishnan and Alley2009) used passive seismic sensors to record a crack opening towards the bed and to ‘hear’ rushing water for a period of ten minutes at the bed of MacAyeal Ice Stream. These studies offer a tantalizing hint of the potential rapidity with which changes take place in the subglacial hydrological system beneath Antarctica, but improved knowledge requires more extensive deployment in terms of both spatial spread and repeat measurements.

Grand challenges

In the last decade, due to technological advances in remote sensing and exploratory geophysics, coupled with improved theoretical conceptions of subglacial processes beneath the major ice sheets, vast improvements have been made in our knowledge of the ways in which subglacial water is generated, stored, flows beneath and ultimately leaves the Antarctic ice sheet. Some of the grand challenges that now lie ahead are identified and discussed below.

Technological improvements and the expansion of the observational base

To date, technology has been key to observing subglacial hydrological phenomena, whether using geophysical techniques to image the basal environment (e.g. Blankenship et al. Reference Blankenship, Bentley, Rooney and Alley1986, Woodward et al. Reference Woodward, Smith, Ross, Thoma, Corr, King, King, Grosfeld, Tranter and Siegert2010), improving drilling to access it (e.g. Siegert et al. Reference Siegert, Kennicutt II and Bindschadler2011), or in developing new ways of interpreting subglacial hydrological behaviour from spaceborne remote sensing observations of the ice surface (e.g. Fricker et al. Reference Fricker, Scambos, Bindschadler and Padman2007). Regarding the latter, continued observations of ice surface change, such as by CryoSat (McMillan et al. Reference McMillan, Corr, Shepherd, Ridout, Laxon and Cullen2013) and IceSAT/IceBridge programs (Fricker et al. Reference Fricker, Scambos, Carter, Davis, Haran and Joughin2010), offer efficient data capture, could be targeted over predicted subglacial lakes and water flowpaths (cf. Livingstone et al. Reference Livingstone, Clark, Woodward and Kingslake2013), and calibrated with field measurements over inferred lakes (e.g. Christianson et al. Reference Christianson, Jacobel, Horgan, Anandakrishnan and Alley2012, Siegert et al. Reference Siegert, Ross, Corr, Smith, Jordan, Bingham, Ferraccioli, Rippin and Le Brocq2014). At the same time, it is important not to neglect observational programmes on and over the ice that could pick up subglacial hydrological changes too subtle to be detected by spaceborne remote sensing, but which may still significantly impact on ice dynamics. Radar instrumentation and processing is one area in which advances have been particularly apparent over the last decade, driven in part by the NASA IceBridge program. Research into beam-forming processing techniques offers the exciting potential for a multi-antennae array to survey swaths of the ice bed, similar to bathymetric multi-beam sonar surveying, vastly improving the efficiency of radar surveys (Paden et al. Reference Paden, Akins, Dunson, Allen and Gogineni2010, Wu et al. Reference Wu, Jezek, Rodriguez, Gogineni, Rodriguez-Morales and Freeman2011). The development and application of ultra-wide-band sensors (e.g. Laird et al. Reference Laird, Blake, Matsuoka, Conway, Allen, Leucschen and Gogineni2010) offer similar prospects for extracting basal properties at an increasing resolution. These advances will require an increased understanding of how radar signals interact with the ice bed interface, in particular with shallow lake environments (e.g. Gorman & Siegert Reference Gorman and Siegert1999). One method to decrease this ambiguity is through the increased use of reflectivity modelling with both real and synthetic datasets (e.g. MacGregor et al. Reference MacGregor, Anandakrishnan, Catania and Winebrenner2011). A significant challenge for radar surveying lies in improving the treatment of englacial attenuation (e.g. Matsuoka et al. Reference Matsuoka, MacGregor and Pattyn2010, Matsuoka Reference Matsuoka2011, Ashmore et al. Reference Ashmore, Bingham, Hindmarsh, Corr and Joughin2014) and improving our ability to discriminate between water at the bed versus contrasts in subglacial geology. Undertaking radar surveys in tandem with seismic surveys (e.g. Murray et al. Reference Murray, Corr, Forieri and Smith2008) or potential-field surveying (e.g. Smith et al. Reference Smith, Jordan, Ferraccioli and Bingham2013) offers promise for these objectives. Completing combined seismic and radar surveys over larger areas would be aided significantly by new seismic instrumentation. Truck-mounted swept-frequency sources (Vibroseis), as are used in terrestrial hydrocarbon exploration, with snow streamer receivers (Hofstede et al. Reference Hofstede, Eisen, Diez, Jansen, Kristoffersen, Lambrecht and Mayer2013), offer a more efficient method for seismic data collection in the future. While a programme of direct-access measurements of hydrology at the ice base would offer the most direct observations, it would be expensive and logistically challenging. Therefore, in the medium-term, our best hope of acquiring observations to improve understanding of subglacial hydrology remains with continuing geophysical survey programmes, especially the use of radar to identify hydrological variability.

Improved understanding of the geothermal heat flux in Antarctica

With supraglacial meltwater inputs to the subglacial system precluded in Antarctica, one of the root causes of subglacial hydrological variability is probably spatial and temporal variations in the generation of subglacial meltwater at the ice sheet base. Therefore, a key objective must be to obtain an improved understanding of a chief control on subglacial meltwater generation, namely the geothermal heat flux, thereby predicting the magnitude of subglacial melt from different regions beneath the ice sheet. Spatial maps of geothermal heat flux based on global seismic modelling (Shapiro & Ritzwoller Reference Shapiro and Ritzwoller2004) or satellite magnetic measurements (Maule et al. Reference Maule, Purucker, Olsen and Mosegaard2005) are currently being used, in part, to derive first-order estimates of subglacial melt (e.g. Pattyn Reference Pattyn2010). However, without direct measurements to calibrate these maps, and considering that in some locations they differ enormously in their distributions, there remains considerable uncertainty over the magnitude of geothermal heat flux in many locations. Ultimately, an integrated multi-dataset-based geothermal heat flux model is required for Antarctica, similar to that produced for Greenland (cf. Rogozhina et al. Reference Rogozhina, Hagedoom, Martinec, Fleming, Soucek, Greve and Thomas2012). Additional datasets that could be used to support such an objective include airborne- and satellite-acquired gravity data (e.g. Vaughan et al. Reference Vaughan, Smith, Nath and Le Meur2003), as well as calibration from rapid-access drilling to the bed of the ice sheet in as many locations as possible, and the use of subglacial lakes and other radar-imaged ‘wet’ basal returns to calibrate locations of warm-based ice.

Improved understanding of subglacial water flowpaths and mechanisms

While most modelling of subglacial water flowpaths in Antarctica has assumed that subglacial water follows distributed flowpaths, the findings of Le Brocq et al. (Reference Le Brocq, Ross, Griggs, Bingham, Corr, Ferraccioli, Jenkins, Jordan, Payne, Rippin and Siegert2013) suggest that channelized flowpaths can exist from some way inland of the grounding line. Hence, a challenge ahead is to discern what conditions are required to keep large subglacial channels open beneath ice streams, and understand the impact this may have on overlying ice dynamics. As part of engaging with this challenge, a requirement will be to understand how the subglacial drainage system may evolve beneath an ice stream in the absence of supraglacial forcing, which is known to be the chief forcing mechanism behind subglacial drainage system evolution in alpine and Arctic systems (cf. Nienow et al. Reference Nienow, Sharp and Willis1998, Bartholomew et al. Reference Bartholomew, Nienow, Mair, Hubbard, King and Sole2010). Subglacial lakes, in particular the regular or irregular drainage from upstream to downstream locations and ultimately to the ice margin, represent one mechanism for initiating the large subglacial water flows one might conceive are necessary for channelization, but how channels remain open underneath deep ice for periods exceeding the length of each drainage event is unknown. Repeat seismic surveys of Rutford Ice Stream have been informative on the changing subglacial environment (Smith et al. Reference Smith, Murray, Nicholls, Makinson, Adalgeirsdóttir, Behar and Vaughan2007) but remain time-consuming and below the temporal resolution of hydrological changes. Geophysical installations, as have been performed in Alpine environments (Kulessa et al. Reference Kulessa, Booth, Hobbs and Hubbard2008), may provide information on subglacial hydrological dynamics at higher temporal resolution. Passive seismic and GPS installations, in particular, may be useful for elucidating the temporal aspect of subglacial drainage and the interaction of water with the substrate (e.g. Winberry et al. Reference Winberry, Anandakrishnan and Alley2009, Reference Winberry, Anandakrishnan, Wiens, Alley and Christianson2011).

Determining the role of subglacial water in ice sheet mass balance

The demonstrable dynamism in subglacial water beneath Antarctica throws into doubt the previously unstated assumption that the role of subglacial water in ice sheet mass balance is negligible. In interior regions, for example, local mass balance may be affected by the widespread phenomenon of substantial volumes of subglacial melt freezing back on to the underside of the ice at bedrock perturbations to form large blocks of accreted ice. This not only removes water that would otherwise have drained downstream, but also affects the internal flow properties of the ice (Bell et al. Reference Bell, Ferraccioli, Creyts, Braaten, Corr, Das, Damaske, Frearson, Jordan, Rose, Studinger and Wolovick2011). On the scale of an ice sheet, the amount of water that is lost to groundwater flow beneath the ice is unknown, and there is limited knowledge of typical volumes of water lost to outburst events at the margin. There is only one published observation of an active subglacial outburst from the Antarctic ice sheet (Law Dome, East Antarctica; Goodwin Reference Goodwin1988), and it is probable that most meltwater leaves the ice sheet unobserved across the grounding line and directly into the ocean. One aspect of subglacial water routing, not considered until now, was described by Uemera et al. (Reference Uemura, Taniguchi and Shibuya2011) who measured an upward freshwater groundwater flux offshore of East Antarctica, which may have been re-emerging subglacial meltwater. New and innovative ways are required to identify probable water outflows from the Antarctic ice sheet and their impact on the ice sheet mass balance.

Uniting geomorphology and process-glaciology to consolidate understanding

For many years, the labyrinthine landscape of subglacially-carved channels exposed in the Dry Valleys of East Antarctica, studied by David Sugden and colleagues (cf. Sugden & John Reference Sugden and John1976 p. 1, Sugden et al. Reference Sugden, Bentley and Ó Cofaigh2006), has presented clear evidence not only that subglacial water flows occur beneath the Antarctic ice sheet, but that they occur with sufficient magnitudes to scour their signal clearly across the subglacial surface, even where that surface consists of hard rock. Offshore from the present-day Antarctic coastline, across the continental shelf which lay under an expanded ice sheet during the Last Glacial Maximum, there is ample evidence of abundant channels and cavities carved into the subglacial surface by inferred subglacial drainage pathways (e.g. Nitsche et al. Reference Nitsche, Gohl, Larter, Hillenbrand, Kuhn, Smith, Jacobs, Anderson and Jakobsson2013). The existence of these signals across the landscape invites the question: how effective is subglacial drainage beneath the Antarctic ice sheet as an active erosional agent, and how effective is it at transporting material from the ice sheet interior to the margin? More generally, it serves as the latest refresher that there is much to be gained from continual knowledge transfer and exchange of ideas between the glacial geomorphology and process-glaciology communities.

Acknowledgements

DWA and RGB wish to thank the University of Aberdeen College of Physical Sciences, the Scottish Alliance for Geoscience, Environment and Society, and the Royal Astronomical Society for financial support towards the production of this paper. We also thank David Rippin, an anonymous reviewer, and the scientific editor Andrew Mackintosh for thorough reviews that benefitted the final manuscript.

References

Alley, R.B., Blankenship, D.D., Rooney, S.T. & Bentley, C.R. 1989. Water-pressure coupling of sliding and bed deformation. 3. Application to ice stream B, Antarctica. Journal of Glaciology, 35, 130139.CrossRefGoogle Scholar
Anandakrishnan, S. & Alley, R.B. 1997. Stagnation of ice stream C, West Antarctica, by water piracy. Geophysical Research Letters, 24, 265268.Google Scholar
Ashmore, D.W., Bingham, R.G., Hindmarsh, R.C.A., Corr, H.F.J. & Joughin, I.R. 2014. The relationship between sticky spots and radar reflectivity beneath an active West Antarctic ice stream. Annals of Glaciology, 55, 2938.Google Scholar
Baker, V.R. & Bunker, R.C. 1985. Cataclysmic Late Pleistocene flooding from Glacial Lake Missoula: a review. Quaternary Science Reviews, 4, 141.CrossRefGoogle Scholar
Bamber, J.L., Gomez-Dans, J.L. & Griggs, J.A. 2009. A new 1 km digital elevation model of the Antarctic derived from combined satellite radar and laser data. Part 1: Data and methods. Cryosphere, 3, 101111.Google Scholar
Bartholomew, I., Nienow, P., Mair, D., Hubbard, A., King, M.A. & Sole, A. 2010. Seasonal evolution of subglacial drainage and acceleration in a Greenland outlet glacier. Nature Geoscience, 3, 408411.Google Scholar
Bell, R.E., Studinger, M., Shuman, C.A., Fahnestock, M.A. & Joughin, I. 2007. Large subglacial lakes in East Antarctica at the onset of fast-flowing ice streams. Nature, 445, 904907.CrossRefGoogle ScholarPubMed
Bell, R.E., Studinger, M., Tikku, A.A., Clarke, G.K.C., Gutner, M.M. & Meertens, C. 2002. Origin and fate of Lake Vostok water frozen to the base of the East Antarctic Ice Sheet. Nature, 416, 307310.CrossRefGoogle Scholar
Bell, R.E., Ferraccioli, F., Creyts, T.T., Braaten, D., Corr, H., Das, I., Damaske, D., Frearson, N., Jordan, T., Rose, K., Studinger, M. & Wolovick, M. 2011. Widespread persistent thickening of the East Antarctic Ice Sheet by freezing from the base. Science, 331, 15921595.Google Scholar
Bentley, C.R., Lord, N. & Liu, C. 1998. Radar reflections reveal a wet bed beneath stagnant ice stream C and a frozen bed beneath ridge BC, West Antarctica. Journal of Glaciology, 44, 149156.CrossRefGoogle Scholar
Bentley, M.J., Christoffersen, P., Hodgson, D.A., Smith, A.M., Tulaczyk, S. & Le Brocq, A.M. 2011. Subglacial lake sediments and sedimentary processes: potential archives of ice sheet evolution, past environmental change, and the presence of life. Geophysical Monograph, 192, 83110.Google Scholar
Bingham, R.G., Hubbard, A.L., Nienow, P.W. & Sharp, M.J. 2008. An investigation into the mechanisms controlling seasonal speedup events at a High Arctic glacier. Journal of Geophysical Research - Earth Surface, 113, 10.1029/2007JF000832.Google Scholar
Blankenship, D.D., Bentley, C.R., Rooney, S.T. & Alley, R.B. 1986. Seismic measurements reveal a saturated porous layer beneath an active Antarctic ice stream. Nature, 322, 5457.Google Scholar
Blankenship, D.D., Bell, R.E., Hodge, S.M., Brozena, J.M., Behrendt, J.C. & Finn, C.A. 1993. Active volcanism beneath the West Antarctic Ice Sheet and implications for ice-sheet stability. Nature, 361, 526529.Google Scholar
Carter, S.P. & Fricker, H.A. 2012. The supply of subglacial meltwater to the grounding line of the Siple Coast, West Antarctica. Annals of Glaciology, 53, 267280.Google Scholar
Carter, S.P., Blankenship, D.D., Young, D.A. & Holt, J.W. 2009a. Using radar-sounding to identify the distribution and sources of subglacial water: application to Dome C, East Antarctica. Journal of Glaciology, 55, 10251040.CrossRefGoogle Scholar
Carter, S.P., Blankenship, D.D., Peters, M.E., Young, D.A., Holt, J.W. & Morse, D.L. 2007. Radar-based subglacial lake classification in Antarctica. Geochemistry Geophysics Geosystems, 8, 10.1029/2006GC001408.Google Scholar
Carter, S.P., Blankenship, D.D., Young, D.A., Peters, M.E., Holt, J.W. & Siegert, M.J. 2009b. Dynamic distributed drainage implied by the flow evolution of the 1996–1998 Adventure Trench subglacial lake discharge. Earth and Planetary Science Letters, 283, 2437.Google Scholar
Catania, G.A., Scambos, T.A., Conway, H. & Raymond, C.F. 2006. Sequential stagnation of Kamb Ice Stream, West Antarctica. Geophysical Research Letters, 33, 10.1029/2006GL026430.CrossRefGoogle Scholar
Catania, G.A., Conway, H.B., Gades, A.M., Raymond, C.F. & Engelhardt, H. 2003. Bed reflectivity beneath inactive ice streams in West Antarctica. Annals of Glaciology, 36, 287291.CrossRefGoogle Scholar
Catania, G., Hulbe, C., Conway, H., Scambos, T.A. & Raymond, C.F. 2012. Variability in the mass flux of the Ross ice streams, West Antarctica, over the last millennium. Journal of Glaciology, 58, 741752.CrossRefGoogle Scholar
Christianson, K., Jacobel, R.W., Horgan, H.J., Anandakrishnan, S. & Alley, R.B. 2012. Subglacial Lake Whillans: ice-penetrating radar and GPS observations of a shallow active reservoir beneath a West Antarctic ice stream. Earth and Planetary Science Letters, 331, 237245.Google Scholar
Christoffersen, P. & Tulaczyk, S. 2003. Response of subglacial sediments to basal freeze-on – 1. Theory and comparison to observations from beneath the West Antarctic Ice Sheet. Journal of Geophysical Research - Solid Earth, 108, 10.1029/2002JB001935.Google Scholar
Christoffersen, P., Tulaczyk, S. & Behar, A. 2010. Basal ice sequences in Antarctic ice stream: exposure of past hydrologic conditions and a principal mode of sediment transfer. Journal of Geophysical Research - Earth Surface, 115, 10.1029/2009JF001430.CrossRefGoogle Scholar
Corr, H.F.J. & Vaughan, D.G. 2008. A recent volcanic eruption beneath the West Antarctic Ice Sheet. Nature Geoscience, 1, 122125.Google Scholar
Cuffey, K.M. & Paterson, W.S.B. 2010. The physics of glaciers, 4th ed. Amsterdam: Elsevier, 704 pp.Google Scholar
Denton, G.H. & Sugden, D.E. 2005. Meltwater features that suggest Miocene ice-sheet overriding of the Transantarctic Mountains in Victoria Land, Antarctica. Geografiska Annaler - Physical Geography, 87A, 6785.CrossRefGoogle Scholar
De Rydt, J., Gudmundsson, G.H., Corr, H.F.J. & Christoffersen, P. 2013. Surface undulations of Antarctic ice streams tightly controlled by bedrock topography. Cryosphere, 7, 407417.CrossRefGoogle Scholar
Dowdeswell, J.A. & Siegert, M.J. 2003. The physiography of modern Antarctic subglacial lakes. Global and Planetary Change, 35, 221236.Google Scholar
Engelhardt, H. & Kamb, B. 1997. Basal hydraulic system of a West Antarctic ice stream: constraints from borehole observations. Journal of Glaciology, 43, 207230.Google Scholar
Engelhardt, H. & Kamb, B. 2013. Kamb Ice Stream flow history and surge potential. Annals of Glaciology, 54, 287298.Google Scholar
Engelhardt, H., Humphrey, N., Kamb, B. & Fahnestock, M. 1990. Physical conditions at the base of a fast moving Antarctic ice stream. Science, 248, 5759.CrossRefGoogle ScholarPubMed
Evatt, G.W., Fowler, A.C., Clark, C.D. & Hulton, N.R.J. 2006. Subglacial floods beneath ice sheets. Philosophical Transactions of the Royal Society, 364A, 17691794.Google Scholar
Fountain, A.G. & Walder, J.S. 1998. Water flow through temperate glaciers. Reviews of Geophysics, 36, 299328.CrossRefGoogle Scholar
Fricker, H.A. & Scambos, T. 2009. Connected subglacial lake activity on lower Mercer and Whillans ice streams, West Antarctica, 2003–2008. Journal of Glaciology, 55, 303315.Google Scholar
Fricker, H.A., Scambos, T., Bindschadler, R. & Padman, L. 2007. An active subglacial water system in West Antarctica mapped from space. Science, 315, 15441548.Google Scholar
Fricker, H.A., Scambos, T., Carter, S., Davis, C., Haran, T. & Joughin, I. 2010. Synthesizing multiple remote-sensing techniques for subglacial hydrologic mapping: application to a lake system beneath MacAyeal Ice Stream, West Antarctica. Journal of Glaciology, 56, 187199.Google Scholar
Fricker, H.A., Powell, R. & Priscu, J. & 11 others. 2011. Siple Coast subglacial aquatic environments: the Whillans Ice Stream Subglacial Access Research Drilling Project. Geophysical Monograph, 192, 199219.Google Scholar
Fujita, S., Holmlund, P., Matsuoka, K., Enomoto, H., Fukai, K., Nakazawa, F., Sugiyama, S. & Surdyk, S. 2012. Radar diagnosis of the subglacial conditions in Dronning Maud Land, East Antarctica. Cryosphere, 6, 12031219.CrossRefGoogle Scholar
Gades, A.M. 1998. Spatial and temporal variations of basal conditions beneath glaciers and ice sheets inferred from radio echo sounding. PhD thesis, University of Washington, 192 pp. [Unpublished.]Google Scholar
Gades, A.M., Raymond, C.F., Conway, H. & Jacobel, R.W. 2000. Bed properties of Siple Dome and adjacent ice streams, West Antarctica, inferred from radio-echo sounding measurements. Journal of Glaciology, 46, 8894.Google Scholar
Glasser, N.F. & Scambos, T.A. 2008. A structural glaciological analysis of the 2002 Larsen B ice-shelf collapse. Journal of Glaciology, 54, 316.CrossRefGoogle Scholar
Goodwin, I.D. 1988. The nature and origin of a jökulhlaup near Casey Station, Antarctica. Journal of Glaciology, 34, 95101.Google Scholar
Gorman, M.R. & Siegert, M.J. 1999. Penetration of Antarctic subglacial Lakes by VHF electromagnetic pulses: information on depth and electrical conductivity of basal water bodies. Journal of Geophysical Research - Solid Earth, 104, 29 31129 320.CrossRefGoogle Scholar
Gray, L., Joughin, I., Tulaczyk, S., Spikes, V.B., Bindschadler, R. & Jezek, K. 2005. Evidence for subglacial water transport in the West Antarctic Ice Sheet through three-dimensional satellite radar interferometry. Geophysical Research Letters, 32, 10.1029/2004GL021387.CrossRefGoogle Scholar
Helière, F., Lin, C.-C., Corr, H. & Vaughan, D. 2007. Radio echo sounding of Pine Island Glacier, West Antarctica: aperture synthesis processing and analysis of feasibility from space. IEEE Transactions on Geoscience and Remote Sensing, 45, 25732582.Google Scholar
Hock, R. & Hooke, R.L. 1993. Evolution of the internal drainage system in the lower part of the ablation area of Storglaciären, Sweden. Geological Society of America Bulletin, 105, 537546.Google Scholar
Hofstede, C., Eisen, O., Diez, A., Jansen, D., Kristoffersen, Y., Lambrecht, A. & Mayer, C. 2013. Investigating englacial reflections with vibro- and explosive-seismic surveys at Halvfarryggen ice dome, Antarctica. Annals of Glaciology, 54, 189200.Google Scholar
Horgan, H.J., Anandakrishnan, S., Jacobel, R.W., Christianson, K., Alley, R.B., Heeszel, D.S., Picotti, S. & Walter, J.I. 2012. Subglacial Lake Whillans: seismic observations of a shallow active reservoir beneath a West Antarctic ice stream. Earth and Planetary Science Letters, 331, 201209.Google Scholar
Hubbard, B. & Nienow, P. 1997. Alpine subglacial hydrology. Quaternary Science Reviews, 16, 939955.Google Scholar
Hulbe, C.L. & Fahnestock, M.L. 2007. Century-scale discharge, stagnation and reactivation of the Ross ice streams, West Antarctica. Journal of Geophysical Research - Earth Surface, 112, 10.1029/2006JF000603.Google Scholar
Hulbe, C.L., Scambos, T.A., Youngberg, T. & Lamb, A.K. 2008. Patterns of glacier response to disintegration of the Larsen B ice shelf, Antarctic Peninsula. Global and Planetary Change, 63, 18.Google Scholar
Iken, A. & Bindschadler, R.A. 1986. Combined measurements of subglacial water pressure and surface velocity of Findelengletscher, Switzerland: conclusions about drainage system and sliding mechanism. Journal of Glaciology, 32, 101119.CrossRefGoogle Scholar
Jacobel, R.W., Welch, B.C., Osterhouse, D., Pettersson, R. & MacGregor, J.A. 2009. Spatial variation of radar-derived basal conditions on Kamb Ice Stream, West Antarctica. Annals of Glaciology, 50, 1016.Google Scholar
Jacobel, R.W., Lapo, K.E., Stamp, J.R., Youngblood, B.W., Welch, B.C. & Bamber, J.L. 2010. A comparison of basal reflectivity and ice velocity in East Antarctica. Cryosphere, 4, 447452.Google Scholar
Kamb, B. 1987. Glacier surge mechanism based on linked cavity configuration of the basal water conduit system. Journal of Geophysical Research - Solid Earth and Planets, 92, 90839100.CrossRefGoogle Scholar
King, E.C., Hindmarsh, R.C.A. & Stokes, C.R. 2009. Formation of mega-scale glacial lineations observed beneath a West Antarctic ice stream. Nature Geoscience, 2, 585588.CrossRefGoogle Scholar
King, E.C., Woodward, J. & Smith, A.M. 2004. Seismic evidence for a water-filled canal in deforming till beneath Rutford Ice Stream, West Antarctica. Geophysical Research Letters, 31, 10.1029/2004GL020379.Google Scholar
Kulessa, B., Booth, A.D., Hobbs, A. & Hubbard, A.L. 2008. Automated monitoring of subglacial hydrological processes with ground-penetrating radar (GPR) at high temporal resolution: scope and potential pitfalls. Geophysical Research Letters, 35, 10.1029/2008GL035855.Google Scholar
Laird, C.M., Blake, W.A., Matsuoka, K., Conway, H., Allen, C.T., Leucschen, C.J. & Gogineni, S. 2010. Deep ice stratigraphy and basal conditions in central West Antarctica revealed by coherent radar. IEEE Geoscience and Remote Sensing Letters, 7, 246250.CrossRefGoogle Scholar
Langley, K., Kohler, J., Matsuoka, K., Sinisalo, A., Scambos, T., Neumann, T., Muto, A., Winther, J.G. & Albert, M. 2011. Recovery Lakes, East Antarctica: radar assessment of sub-glacial water extent. Geophysical Research Letters, 38, 10.1029/2010GL046094.Google Scholar
Le Brocq, A.M., Payne, A.J., Siegert, M.J. & Alley, R.B. 2009. A subglacial water-flow model for West Antarctica. Journal of Glaciology, 55, 879888.Google Scholar
Le Brocq, A.M., Ross, N., Griggs, J.A., Bingham, R.G., Corr, H.F.J., Ferraccioli, F., Jenkins, A., Jordan, T.A., Payne, A.J., Rippin, D.M. & Siegert, M.J. 2013. Evidence from ice shelves for channelized meltwater flow beneath the Antarctic ice sheet. Nature Geoscience, 6, 945948.Google Scholar
Lewis, A.R., Marchant, D.R., Kowalewski, D.E., Baldwin, S.L. & Webb, L.E. 2006. The age and origin of the Labyrinth, western Dry Valleys, Antarctica: evidence for extensive middle Miocene subglacial floods and water freshwater discharge into the Southern Ocean. Geology, 34, 513516.Google Scholar
Livingstone, S.J., Clark, C.D., Woodward, J. & Kingslake, J. 2013. Potential subglacial lake locations and meltwater drainage pathways beneath the Antarctic and Greenland ice sheets. Cryosphere, 7, 17211740.Google Scholar
MacGregor, J.A., Anandakrishnan, S., Catania, G.A. & Winebrenner, D.P. 2011. The grounding zone of the Ross Ice Shelf, West Antarctica, from ice-penetrating radar. Journal of Glaciology, 57, 917928.Google Scholar
MacGregor, J.A., Catania, G.A., Conway, H., Schroeder, D.M., Joughin, I., Young, D.A., Kempf, S.D. & Blankenship, D.D. 2013. Weak bed control of the eastern shear margin of Thwaites Glacier, West Antarctica. Journal of Glaciology, 59, 900912.Google Scholar
McMillan, M., Corr, H., Shepherd, A., Ridout, A., Laxon, S. & Cullen, R. 2013. Three-dimensional mapping by CryoSat-2 of subglacial lake volume changes. Geophysical Research Letters, 40, 43214327.Google Scholar
Mair, D., Nienow, P., Sharp, M.J., Wohlleben, T. & Willis, I. 2002. Influence of subglacial drainage system evolution on glacier surface motion: Haut Glacier d’Arolla, Switzerland. Journal of Geophysical Research - Solid Earth, 107, 10.1029/2001JB000514.Google Scholar
Marchant, D.R., Jamieson, S.S.R. & Sugden, D.E. 2011. The geomorphic signature of massive subglacial floods in Victoria Land, Antarctica. Geophysical Monograph, 192, 111126.Google Scholar
Margerison, H.R., Phillips, W.M., Stuart, F.M. & Sugden, D.E. 2005. Cosmogenic 3He concentrations in ancient flood deposits from the Coombs Hills, northern Dry Valleys, East Antarctica: interpreting exposure ages and erosion rates. Earth and Planetary Science Letters, 230, 163175.Google Scholar
Matsuoka, K. 2011. Pitfalls in radar diagnosis of ice-sheet bed conditions: lessons from englacial attenuation models. Geophysical Research Letters, 38, 10.1029/2010GL046205.Google Scholar
Matsuoka, K., MacGregor, J.A. & Pattyn, F. 2010. Using englacial radar attenuation to better diagnose the subglacial environment: a review. 13th International Conference on Ground Penetrating Radar (GPR), 19–23 June, 2010. GPR Proceedings 2010, 10.1109/ICGPR.2010.5550161.Google Scholar
Matsuoka, K., Pattyn, F., Callens, D. & Conway, H. 2012. Radar characterization of the basal interface across the grounding zone of an ice-rise promontory in East Antarctica. Annals of Glaciology, 53, 2934.CrossRefGoogle Scholar
Matsuoka, K., Gades, A., Conway, H., Catania, G. & Raymond, C.F. 2009. Radar signatures beneath a surface topographic lineation near the outlet of Kamb Ice Stream and Engelhardt Ice Ridge, West Antarctica. Annals of Glaciology, 50, 98104.Google Scholar
Maule, C.F., Purucker, M.E., Olsen, N. & Mosegaard, K. 2005. Heat flux anomalies in Antarctica revealed by satellite magnetic data. Science, 309, 464467.Google Scholar
Müller, F. & Iken, A. 1973. Velocity fluctuations and water regime of arctic valley glaciers. International Association of Scientific Hydrology Publications, 95, 165182.Google Scholar
Murray, T., Corr, H., Forieri, A. & Smith, A.M. 2008. Contrasts in hydrology between regions of basal deformation and sliding beneath Rutford Ice Stream, West Antarctica, mapped using radar and seismic data. Geophysical Research Letters, 35, 10.1029/2008GL033681.Google Scholar
Nienow, P., Sharp, M. & Willis, I. 1998. Seasonal changes in the morphology of the subglacial drainage system, Haut Glacier d’Arolla, Switzerland. Earth Surface Processes and Landforms, 23, 825843.Google Scholar
Nitsche, F.O., Gohl, K., Larter, R.D., Hillenbrand, C.D., Kuhn, G., Smith, J.A., Jacobs, S., Anderson, J.B. & Jakobsson, M. 2013. Paleo ice flow and subglacial meltwater dynamics in Pine Island Bay, West Antarctica. Cryosphere, 7, 249262.Google Scholar
Paden, J., Akins, T., Dunson, D., Allen, C. & Gogineni, P. 2010. Ice-sheet bed 3-D tomography. Journal of Glaciology, 56, 311.CrossRefGoogle Scholar
Pattyn, F. 2010. Antarctic subglacial conditions inferred from a hybrid ice sheet/ice stream model. Earth and Planetary Science Letters, 295, 451461.Google Scholar
Pattyn, F. 2011. Antarctic subglacial lake discharges. Geophysical Monograph, 192, 2744.Google Scholar
Pattyn, F., De Brabander, S. & Huyghe, A. 2005. Basal and thermal control of the Ragnhild glaciers, East Antarctica. Annals of Glaciology, 40, 225231.Google Scholar
Pattyn, F., De Smedt, B. & Souchez, R. 2004. Influence of subglacial Vostok Lake on the regional ice dynamics of the Antarctic ice sheet: a model study. Journal of Glaciology, 50, 583589.Google Scholar
Payne, A.J., Holland, P.R., Shepherd, A.P., Rutt, I.C., Jenkins, A. & Joughin, I. 2007. Numerical modelling of ocean-ice interactions under Pine Island Bay’s ice shelf. Journal of Geophysical Research - Oceans, 112, 10.1029/2006JC003733.Google Scholar
Peters, L.E., Anandakrishnan, S., Alley, R.B. & Smith, A.M. 2007. Extensive storage of basal meltwater in the onset region of a major West Antarctic ice stream. Geology, 35, 251254.Google Scholar
Peters, M.E., Blankenship, D.D. & Morse, D.L. 2005. Analysis techniques for coherent airborne radar sounding: application to West Antarctic ice streams. Journal of Geophysical Research - Solid Earth, 110, 10.1029/2004JB003222.Google Scholar
Peters, M.E., Blankenship, D.D., Carter, S.P., Kempf, S.D., Young, D.A. & Holt, J.W. 2007. Along-track focusing of airborne radar sounding data from West Antarctica for improving basal reflection analysis and layer detection. IEEE Transactions on Geoscience and Remote Sensing, 45, 27252736.CrossRefGoogle Scholar
Price, S.F., Payne, A.J., Catania, G.A. & Neumann, T.A. 2008. Seasonal acceleration of inland ice via longitudinal coupling to marginal ice. Journal of Glaciology, 54, 213219.Google Scholar
Priscu, J.C., Adams, E.E., Lyons, W.B., Voytek, M.A., Mogk, D.W., Brown, R.L., McKay, C.P., Takacs, C.D., Welch, K.A., Wolf, C.F., Kirshtein, J.D. & Avci, R. 1999. Geomicrobiology of subglacial ice above Lake Vostok, Antarctica. Science, 286, 21412144.Google Scholar
Pritchard, H.D., Arthern, R.J., Vaughan, D.G. & Edwards, L.A. 2009. Extensive dynamic thinning on the margins of the Greenland and Antarctic ice sheets. Nature, 461, 971975.Google Scholar
Raymond, C.F., Catania, G.A., Nereson, N. & van der Veen, C.F. 2006. Bed radar reflectivity across the north margin of Whillans Ice Stream, West Antarctica, and implications for margin processes. Journal of Glaciology, 52, 310.Google Scholar
Rémy, F. & Legrésy, B. 2005. Subglacial hydrological networks in Antarctica and their impact on ice flow. Annals of Glaciology, 39, 6772.CrossRefGoogle Scholar
Retzlaff, R. & Bentley, C.R. 1993. Timing of stagnation of Ice Stream C, West Antarctica, from short-pulse radar studies of buried surface crevasses. Journal of Glaciology, 39, 553561.Google Scholar
Ridley, J.K., Cudlip, W. & Laxon, S.W. 1993. Identification of subglacial lakes using ERS-1 radar altimeter. Journal of Glaciology, 39, 625634.Google Scholar
Rignot, E., Mouginot, J. & Scheuchl, B. 2011. Ice flow of the Antarctic ice sheet. Science, 333, 14271430.Google Scholar
Rippin, D.M., Bamber, J.L., Siegert, M.J., Vaughan, D.G. & Corr, H.F.J. 2003. Basal topography and ice flow in the Bailey/Slessor region of East Antarctica. Journal of Geophysical Research - Earth Surface, 108, 10.1029/2003JF000039.Google Scholar
Rippin, D.M., Bamber, J.L., Siegert, M.J., Vaughan, D.G. & Corr, H.F.J. 2004. The role of ice thickness and bed properties on the dynamics of the enhanced-flow tributaries of Bailey Ice Stream and Slessor Glacier, East Antarctica. Annals of Glaciology, 39, 366372.Google Scholar
Robin, G.D.Q., Drewry, D.J. & Meldrum, D.T. 1977. International studies of ice sheet and bedrock. Philosophical Transactions of the Royal Society, 279B, 185196.Google Scholar
Rogozhina, I., Hagedoom, J.M., Martinec, Z., Fleming, K., Soucek, O., Greve, R. & Thomas, M. 2012. Effects of uncertainties in the geothermal heat flux distribution on the Greenland ice sheet: an assessment of existing heat flow models. Journal of Geophysical Research - Earth Surface, 117, 10.1029/2011JF002098.Google Scholar
Schroeder, D.M., Blankenship, D.D. & Young, D.A. 2013. Evidence for a water system transition beneath Thwaites Glacier, West Antarctica. Proceedings of the National Academy of Sciences of the United States of America, 110, 12 22512 228.Google Scholar
Shabtaie, S., Whillans, I.M. & Bentley, C.R. 1987. The morphology of Ice Streams A, B, and C, West Antarctica, and their environs. Journal of Geophysical Research - Solid Earth and Planets, 92, 88658883.Google Scholar
Shannon, S.R., Payne, A.J. & Bartholomew, I.D. & 16 others. 2013. Enhanced basal lubrication and the contribution of the Greenland ice sheet to future sea-level rise. Proceedings of the National Academy of Sciences of the United States of America, 110, 14 15614 161.Google Scholar
Shapiro, N.M. & Ritzwoller, M.H. 2004. Inferring surface heat flux distributions guided by a global seismic model: particular application to Antarctica. Earth and Planetary Science Letters, 223, 213224.Google Scholar
Shreve, R.L. 1972. Movement of water in glaciers. Journal of Glaciology, 11, 205214.Google Scholar
Shtarkman, Y.M., Kocer, Z.A., Edgar, R., Veerapaneni, R.S., D’elia, T., Morris, P.F. & Rogers, S.O. 2013. Subglacial Lake Vostok (Antarctica) accretion ice contains a diverse set of sequences from aquatic, marine and sediment-inhabiting bacteria and eukarya. PLoS ONE, 8, 10.1371/journal.pone.0067221.Google Scholar
Siegert, M.J. & Bamber, J.L. 2000. Subglacial water at the heads of Antarctic ice stream tributaries. Journal of Glaciology, 46, 702703.Google Scholar
Siegert, M.J., Kennicutt II, M.C. & Bindschadler, R.A., eds. 2011. Antarctic subglacial aquatic environments. Washington, DC: American Geophysical Union, 246 pp.Google Scholar
Siegert, M.J., Le Brocq, A. & Payne, A.J. 2007. Hydrological connections between Antarctic subglacial lakes, the flow of water beneath the East Antarctic Ice Sheet and implications for sedimentary processes. In Hambrey, M.J., Christoffersen, P., Glasser, N.F. & Hubbard, B., eds. Glacial sedimentary processes and products. Special Publications of the International Association of Sedimentologists, No. 39, 310.Google Scholar
Siegert, M.J., Kwok, R., Mayer, C. & Hubbard, B. 2000. Water exchange between the subglacial Lake Vostok and the overlying ice sheet. Nature, 403, 643646.Google Scholar
Siegert, M.J., Ross, N., Corr, H., Smith, B., Jordan, T., Bingham, R.G., Ferraccioli, F., Rippin, D. & Le Brocq, A. 2014. Boundary conditions of an active West Antarctic subglacial lake: implications for storage of water beneath the ice sheet. Cryosphere, 8, 1524.Google Scholar
Skidmore, M. 2011. Microbial communities in Antarctic subglacial lake aquatic environments. Geophysical Monograph, 192, 6181.Google Scholar
Smith, A.M. 1997a. Basal conditions on Rutford Ice Stream, West Antarctica, from seismic observations. Journal of Geophysical Research - Solid Earth, 102, 543552.Google Scholar
Smith, A.M. 1997b. Variations in basal conditions on Rutford Ice Stream, West Antarctica. Journal of Glaciology, 43, 245255.Google Scholar
Smith, A.M., Jordan, T.A., Ferraccioli, F. & Bingham, R.G. 2013. Influence of subglacial conditions on ice stream dynamics: seismic and potential field data from Pine Island Glacier, West Antarctica. Journal of Geophysical Research - Solid Earth, 118, 14711482.Google Scholar
Smith, A.M., Murray, T., Nicholls, K.W., Makinson, K., Adalgeirsdóttir, G., Behar, A.E. & Vaughan, D.G. 2007. Rapid erosion, drumlin formation, and changing hydrology beneath an Antarctic ice stream. Geology, 35, 127130.Google Scholar
Smith, B.E., Fricker, H.A., Joughin, I.R. & Tulaczyk, S. 2009. An inventory of active subglacial lakes in Antarctica detected by ICESat (2003–2008). Journal of Glaciology, 55, 573595.Google Scholar
Spikes, V.B., Csatho, B.M., Hamilton, G.S. & Whillans, I.M. 2003. Thickness changes on Whillans Ice Stream and Ice Stream C, West Antarctica, derived from laser altimeter measurements. Journal of Glaciology, 49, 223230.Google Scholar
Statham, P.J., Skidmore, M. & Tranter, M. 2008. Inputs of glacially derived dissolved and colloidal iron to the coastal ocean and implications for primary productivity. Global Biogeochemical Cycles, 22, 10.1029/2007GB003106.Google Scholar
Stearns, L.A., Smith, B.E. & Hamilton, G.S. 2008. Increased flow speed on a large East Antarctic outlet glacier caused by subglacial floods. Nature Geoscience, 1, 827831.Google Scholar
Studinger, M., Bell, R.E. & Tikku, A.A. 2004. Estimating the depth and shape of subglacial Lake Vostok’s water cavity from aerogravity data. Geophysical Research Letters, 31, 10.1029/2004GL019801.Google Scholar
Sugden, D. & Denton, G. 2004. Cenozoic landscape evolution of the Convoy Range to Mackay Glacier area, Transantarctic Mountains: onshore to offshore synthesis. Geological Society of America Bulletin, 116, 840857.Google Scholar
Sugden, D.E. & John, B.S. 1976. Glaciers and landscape. London: Arnold, 376 pp.Google Scholar
Sugden, D.E., Bentley, M.J. & Ó Cofaigh, C. 2006. Geological and geomorphological insights into Antarctic ice sheet evolution. Philosophical Transactions of the Royal Society, 364A, 16071625.Google Scholar
Sugden, D.E., Denton, G.H. & Marchant, D.R. 1991. Subglacial meltwater channel systems and ice sheet overriding, Asgard Range, Antarctica. Geografiska Annaler - Physical Geography, 73A, 109121.Google Scholar
Sundal, A.V., Shepherd, A., Nienow, P., Hanna, E., Palmer, S. & Huybrechts, P. 2011. Melt-induced speed-up of Greenland ice sheet offset by efficient subglacial drainage. Nature, 469, 521524.Google Scholar
Tedstone, A.J., Nienow, P.W., Sole, A.J., Mair, D.W.F., Cowton, T.R., Bartholomew, I.D. & King, M.A. 2013. Greenland ice sheet motion insensitive to exceptional meltwater forcing. Proceedings of the National Academy of Sciences of America, 110, 19 71919 724.Google Scholar
Uemura, T., Taniguchi, M. & Shibuya, K. 2011. Submarine groundwater discharge in Lützow-Holm Bay, Antarctica. Geophysical Research Letters, 38, 10.1029/2010GL046394.Google Scholar
Van de Wal, R.S.W., Boot, W., van den Broeke, M.R., Smeets, C.J.P.P., Reijmer, C.H., Donker, J.J.A. & Oerlemans, J. 2008. Large and rapid melt-induced velocity changes in the ablation zone of the Greenland ice sheet. Science, 321, 111113.Google Scholar
Van der Wel, N., Christofferson, P. & Bougamont, M. 2013. The influence of subglacial hydrology on the flow of Kamb Ice Stream, West Antarctica. Journal of Geophysical Research - Earth Surface, 118, 97110.Google Scholar
Van Liefferinge, B. & Pattyn, F. 2013. Using ice-flow models to evaluate potential sites of million year-old ice in Antarctica. Climate of the Past, 9, 23352345.Google Scholar
Vaughan, D.G., Smith, A.M., Nath, P.C. & Le Meur, E. 2003. Acoustic impedance and basal shear stress beneath four Antarctic ice streams. Annals of Glaciology, 36, 225232.Google Scholar
Vaughan, D.G., Corr, H.F.J., Smith, A.M., Pritchard, H.D. & Shepherd, A. 2008. Flow-switching and water piracy between Rutford Ice Stream and Carlson Inlet, West Antarctica. Journal of Glaciology, 54, 4148.Google Scholar
Vogel, S.W. & Tulaczyk, S. 2006. Ice-dynamical constraints on the existence and impact of subglacial volcanism on West Antarctic Ice Sheet stability. Geophysical Research Letters, 33, 10.1029/2006GL027345.Google Scholar
Vogel, S.W., Tulaczyk, S., Kamb, B., Englehardt, H., Carsey, F.D., Behar, A.E., Lane, A.L. & Joughin, I. 2005. Subglacial conditions during and after stoppage of an Antarctic ice stream: is reactivation imminent? Geophysical Research Letters, 32, 10.1029/2005GL022563.Google Scholar
Weertman, J. 1957. On the sliding of glaciers. Journal of Glaciology, 3, 3338.Google Scholar
Winberry, J.P., Anandakrishnan, S. & Alley, R.B. 2009. Seismic observations of transient subglacial water flow beneath MacAyeal Ice Stream, West Antarctica. Geophysical Research Letters, 36, 10.1029/2009GL037730.Google Scholar
Winberry, J.P., Anandakrishnan, S., Wiens, D.A., Alley, R.B. & Christianson, K. 2011. Dynamics of stick-slip motion, Whillans Ice Stream, Antarctica. Earth and Planetary Science Letters, 305, 283289.Google Scholar
Wingham, D.J., Siegert, M.J., Shepherd, A. & Muir, A.S. 2006. Rapid discharge connects Antarctic subglacial lakes. Nature, 440, 10331036.Google Scholar
Wolovick, M.J., Bell, R.E., Creyts, T.T. & Frearson, N. 2013. Identification and control of subglacial water networks under Dome A, Antarctica. Journal of Geophysical Research - Earth Surface, 118, 140154.Google Scholar
Woodward, J., Smith, A.M., Ross, N., Thoma, M., Corr, H.F.J., King, E.C., King, M.A., Grosfeld, K., Tranter, M. & Siegert, M.J. 2010. Location for direct access to subglacial Lake Ellsworth: an assessment of geophysical data and modelling. Geophysical Research Letters, 37, 10.1029/2010GL042884.Google Scholar
Wright, A. & Siegert, M. 2012. A fourth inventory of Antarctic subglacial lakes. Antarctic Science, 24, 659664.Google Scholar
Wright, A.P., Siegert, M.J., Le Brocq, A.M. & Gore, D.B. 2008. High sensitivity of subglacial hydrological pathways in Antarctica to small ice-sheet changes. Geophysical Research Letters, 35, 10.1029/2008GL034937.Google Scholar
Wright, A.P., Young, D.A., Roberts, J.L., Schroeder, D.M., Bamber, J.L., Dowdeswell, J.A., Young, N.W., Le Brocq, A.M., Warner, R.C., Payne, A.J., Blankenship, D.D., van Ommen, T.D. & Siegert, M.J. 2012. Evidence of a hydrological connection between the ice divide and ice sheet margin in the Aurora Subglacial Basin, East Antarctica. Journal of Geophysical Research - Earth Surface, 117, 10.1029/2011JF002066.Google Scholar
Wu, X.Q., Jezek, K.C., Rodriguez, E., Gogineni, S., Rodriguez-Morales, F. & Freeman, A. 2011. Ice sheet bed mapping with airborne SAR tomography. IEEE Transactions on Geoscience and Remote Sensing, 49, 37913803.Google Scholar
Zirizzotti, A., Cafarella, L. & Urbini, S. 2012. Ice and bedrock characteristics underneath Dome C (Antarctica) from radio echo sounding data analysis. IEEE Transactions on Geoscience and Remote Sensing, 50, 3743.Google Scholar
Zirizzotti, A., Cafarella, L., Baskaradas, J.A., Tabacco, I.E., Urbini, S., Mangialetti, M. & Bianchi, C. 2010. Dry-wet bedrock detection by radio echo sounding measurements. IEEE Transactions on Geoscience and Remote Sensing, 48, 23432348.Google Scholar
Zwally, H.J, Abdalati, W., Herring, T., Larson, K., Saba, J. & Steffen, K. 2002. Surface-melt-induced acceleration of Greenland ice-sheet flow. Science, 297, 218222.Google Scholar
Figure 0

Fig. 1 The ‘Labyrinth’ subglacially-formed, and now deglaciated, channel system in western Wright Valley, Dry Valleys region, East Antarctica. Aerial view to the east. Channels are cut into dolerite. Individual channels are up to 100 m deep. The North Fork of Wright Valley is in the upper left background. Some potholes on the interfluves are littered with dolerite blocks, some of which are imbricated (photograph courtesy David Sugden; caption modified from Denton & Sugden 2005).

Figure 1

Fig. 2 Conceptual diagram of the typical situation of subglacial lakes and configuration of water flows beneath the Antarctic ice sheet.

Figure 2

Fig. 3 Antarctic locations referred to in the text, using the ice-surface velocity map of Rignot et al. (2011), superimposed over the MODIS Mosaic of Antarctica as a basemap. The locations of subglacial lakes are denoted by circles, and the subglacial-flood landforms shown in Fig. 1 are located by the black star. An inventory of all known subglacial lake locations in Antarctica is provided by Wright & Siegert (2012). AB=Aurora Basin, AL=Adventure Lakes, BG=Byrd Glacier, BIS=Bindschadler Ice Stream, DA=Dome A, DC=Dome C, DF=Dome F, EAIS=East Antarctic Ice Sheet, EIR=Engelhardt Ice Ridge, EIS=Evans Ice Stream, GSM=Gamburtsev Subglacial Mountains, IIS=Institute Ice Stream, KIS=Kamb Ice Stream, LD=Law Dome, MAIS=MacAyeal Ice Stream, MIS=Mercer Ice Stream, PIG=Pine Island Glacier, RBIS=Roi Baudouin Ice Shelf, RG=Ragnhild Glaciers, RIR=Raymond Ice Ridge, RIS=Rutford Ice Stream, RL=Recovery Lakes, SC=Soya Coast, SD=Siple Dome, SG=Slessor Glacier, SLE=Subglacial Lake Ellsworth, SLV=Subglacial Lake Vostok, SLW=Subglacial Lake Whillans, TD=Taylor Dome, ThwG=Thwaites Glacier, TotG=Totten Glacier, VL=Victoria Land, WAIS=West Antarctic Ice Sheet, WB=Wilkes Basin, WD=WAIS divide, WIS=Whillans Ice Stream, WL=Wilkes Land.

Figure 3

Fig. 4 Radargrams of the West Antarctic subglacial hydrological environment. a. Subglacial highlands near the West Antarctic divide showing steep, complex topography and well-preserved internal layers; note the bright reflection 27 km along-track indicating pooled water. b. The margin of Evans Ice Stream demonstrating the contrast between the ice stream, characterized by a bright reflection and absent-layering (left) and dimmer reflection and well-preserved layering in the slow-moving area (right). c. Flat and bright reflectors at the base of subglacial valleys; note their non-specular nature indicating the presence of saturated sediment, rather than a ‘definite lake’ (cf. Carter et al. 2007).

Figure 4

Table I Summary of radioglaciological studies in which bed-reflection power (bed reflectivity) has been acquired across parts of the Antarctic ice sheet organized chronologically by survey date. Traverses between locations are denoted by hyphenation. Only Antarctic-focused studies from the last 15 years specifically concerned with the basal reflectivity of grounded ice are listed. Bright reflections have been used to (semi-)qualitatively delineate subglacial lakes since the 1960s and such studies are not included here.