Introduction
Understanding the mechanisms that initiate fast flow in ice sheets is critical to understanding how ice sheets respond to external forcings. Potential controls have been summarized by Reference Winsborrow, Clark and StokesWinsborrow and others (2010) and include topographic focusing, topographic steps, macroscale topographic roughness, calving margins, subglacial geology, geothermal heat flux and subglacial meltwater routing. With the exception of the calving margin, each of these controls can play a role in the onset of Recovery Ice Stream, East Antarctica, which occurs over a broad region divided into distinct branches. By comparing the topography, geology and bed conditions across this region, we can compare the relative importance of the control mechanisms in order to better understand the hierarchy of factors that influence ice-stream initiation.
Regional setting
Recovery Ice Stream drains a large catchment covering 8% of the East Antarctic ice sheet (Reference Joughin and BamberJoughin and Bamber, 2005), extending >800 km inland (Reference JezekJezek, 1999) and widening to a broad, 400 km wide region of fast flow (Fig. 1a) organized into multiple branches.
The inland extent of Recovery Ice Stream reaches towards the Recovery Lakes region, on the western edge of the Recovery Highlands. The Recovery Highlands is a 200 km wide mountain belt with average subglacial elevations of 900 m; the rugged topography includes peaks reaching >1600 m a.s.l. (Fig. 1b). The Recovery Lakes region, in contrast, has an average elevation of 600–1500 m below sea level (b.s.l.). In the entire onset region, the bed topography is generally flat, except for the four deep topographic basins that are aligned along the Highlands Lakes boundary, features originally identified as subglacial lakes (Reference Bell, Studinger, Shuman, Fahnestock and JoughinBell and others, 2007; Fig. 1b).
The Recovery Lake basins were first identified from satellite imagery and satellite-derived ice surface elevations (Reference Bell, Studinger, Shuman, Fahnestock and JoughinBell and others, 2007). The three northern lake basins were identified by their relatively flat ice surfaces (Fig. 1c) bounded by 3–15 m surface troughs on the upstream margin and 2–10 m surface ridges on the downstream side, similar features to the well-studied Vostok Subglacial Lake (Reference StudingerStudinger and others, 2003). The Recovery Lake basins are among the largest identified subglacial lake basins in Antarctica (A: 3915 km2; B: 4385 km2; C: 1490 km2; D: 3540 km2) and are comparable in size to Lakes 90°E (2420 km2) and Sovietskaya (1745 km2).
Recent ice radar soundings, incorporated into the BEDMAP2 compilation (Reference FretwellFretwell and others, 2013) and described in more detail below, showed that these basins are ~ 30–50 km wide, with bed depths reaching ~ 1500 m b.s.l. (Fig. 1b). The 800–1000 m topographic step from the Highlands to the lakes represents the well-defined upstream edge of Lakes C and D in flowline profiles across the lake basins (Fig. 2). A smaller 500 m high ridge bounds the upstream edge of both Lakes A and B. The downstream margins of Lakes B, C and D each have similar 500 m high, 20 km wide ridges. The downstream margin of Lake A is more gradual, with no well-defined ridge.
Reference Bell, Studinger, Shuman, Fahnestock and JoughinBell and others (2007) suggested that the presence of water in the Recovery Lakes region is directly linked to the mechanism for onset of streaming, through basal lubrication and accretion of a more readily deformed basal ice layer. While faster flow originates at the downstream end of the lake basins (Reference Rignot, Mouginot and ScheuchlRignot and others, 2011), the pattern of the velocity increase is not uniform for all the lakes. Velocities in these regions are still low, but organized flow can be traced from each onset region into the main trunk of Recovery Glacier. To the north, two relatively fast-flowing narrow branches of the ice stream extend close to the lakes (Fig. 1a), with the fastest-flowing branch of the ice stream reaching close to the western margin of Lake A, where the ice velocity increases steadily once the ice crosses the margin of the basin (Fig. 2b). Less than 50 km downstream of Lake A, ice is moving at 30 m a−1. Along a southern flowline, traversing both Lakes A and B, this speed is not attained until 75 km downstream of the lakes (Fig. 2c).
Farther south, a broad, 100 km wide onset region reaches towards Lakes C and D (Fig. 1a). The increase in velocity from 10 m a−1 to 25 m a−1 begins ~ 200 km down-flow of these lakes, in the region where smaller active lakes have been identified (Reference Smith, Fricker, Joughin and TulaczykSmith and others, 2009; Reference Fricker, Carter, Bell and ScambosFricker and others, 2014). In contrast to Lake A, 50 km from Lake C the ice sheet is moving <20 m a−1, while at the same distance from the down-flow edge of Lake D, it is moving <15 m a−1 (Fig. 2d and e).
The four upper branches of Recovery Ice Stream flow out from the four Recovery Lake basins, but as described, ice velocity develops at different rates from each of the basins. By examining the nature of the lake basins, from their topography, geology and water content, we identify the combination of factors that are critical to the onset of ice streaming in the Recovery catchment.
Methods
Prior to 2009, the morphology of the Recovery lake basins and onset region could only be inferred through very limited measurements of ice thickness and gravity made along a surface traverse route in the 1960s (Reference Clough, Bentley and PosterClough and others, 1968).
New ground and airborne geophysical data were obtained in early 2009, as part of the International Polar Year (IPY). Ground-based radar, gravity and GPS were collected by the US–Norway Traverse in 2008/09 (Reference LangleyLangley and others, 2011) over all four basins, although mostly A and B. Airborne geophysical data (radar, laser, gravity and magnetics) were collected by the AGAP (Antarctica's Gamburtev Province) program in 2009 (Reference BlockBlock, 2011) over the southern two lake basins C and D (Fig. 1). These two datasets are combined to provide the first comprehensive overview of all four lake basins and the onset region.
The ground-based radar data were acquired with a 3 MHz impulse dipole radar (Reference LangleyLangley and others, 2011). Ground-based gravity surveys were performed with a pair of LaCoste–Romberg gravimeters. Two automated long-term GPS measurement stations, configured for measuring vertical motion of the firn at ~ 6 m depth, were deployed on the central Recovery B basin and on a smaller subglacial lake (Rec11 of Smith and others, 2009; Rec9 in Reference Fricker, Carter, Bell and ScambosFricker and others, 2014, Supplementary Material, SM-1, online at http://www.igsoc.org/hyperlink/14j067.pdf) north of the main Recovery basins. The AGAP airborne survey included data from a 150 MHz radar system (Reference BlockBlock, 2011; Reference Wolovick, Bell, Creyts and FrearsonWolovick and others, 2013) and a Sander Geophysics AIRGrav gravimeter (Reference Studinger, Bell and FrearsonStudinger and others, 2008).
We use the radar data to evaluate the presence of water by calculating basal hydraulic head, anomalous bed reflectivity and bed roughness along the survey lines (Reference Oswald and RobinOswald and Robin, 1973; Reference Siegert, Dowdeswell, Gorman and IntyreSiegert and others, 1996; Reference Carter, Blankenship, Peters, Young, Holt and MorseCarter and others, 2007). Hydraulic head is a measure of potential water flow at the bed (Reference Oswald and RobinOswald and Robin, 1973); water will drain in the direction of lower hydraulic head and collect in regions with hydraulic minima (Supplementary Material, SM-1, http://www.igsoc.org/hyperlink/14j067.pdf).
Radar bed-returned power was converted to bed reflectivity following Reference Matsuoka, Morse and RaymondMatsuoka and others (2010), after correcting for system characteristics, a geometric factor proportional to ice thickness, and the depth-averaged oneway attenuation rate (details in Supplementary Material, SM-1, http://www.igsoc.org/hyperlink/14j067.pdf). Bed reflectivity is characterized by the brightness residual, the deviation of the measured value from that predicted for a given attenuation rate. Higher values (or brighter regions) are anticipated over clean ice/water interfaces, as opposed to ice/sediment or grounded ice regions (Reference Winebrenner, Smith, Catania, Conway and RaymondWinebrenner and others, 2003; Reference Jacobel, Welch, Osterhouse, Pettersson and GregorJacobel and others, 2009; Reference LangleyLangley and others, 2011).
Bed roughness is determined from bed elevation data following Reference Rippin, Vaughan and CorrRippin and others (2011), described here by a dimensionless number (details in Supplementary Material, SM-1, http://www.igsoc.org/hyperlink/14j067.pdf). All else being equal, an extensive ice/water interface will have a low roughness value compared to an ice/sediment or ice/rock interface. Radar measurements of ice thickness and bed topography have an accuracy of 12.5 m for the ground-based system (Reference LangleyLangley and others, 2011) and 40 m for the airborne system (Reference BlockBlock, 2011) based on crossover analysis. The vertical range resolution of the two systems is 28 and 0.56 m respectively, based on the bandwidth.
The geological setting of the Recovery Lakes was investigated by comparing the observed gravity anomalies with those predicted from two-dimensional models along the survey lines. Forward models of the gravity across the Recovery Lake basins were constructed assuming three bodies: ice, crustal rock, and mantle (details in Supplementary Material, SM-2, http://www.igsoc.org/hyperlink/14j067.pdf). Bed topography at the ice/crustal-rock interface was identified from the radar surveys, and the crust/mantle boundary was modelled using an Airy approximation and crustal thickness of 43.1 km as determined teleseismically at the AGAP camp (Reference Hansen, Nyblade, Heeszel, Wiens, Shore and KanaoHansen and others, 2010). Smaller-scale forward models of gravity across the lake basins were used to identify the presence or absence of low-density sediments within the lake basins. The same ice and crustal-rock bodies were used as above, but with the long-wavelength gravity field accounted for by applying a linear correction between the upstream and downstream edges of the basins. This allowed us to compare the shape of the anomaly across each basin with that predicted from the measured bed to isolate areas of low-density sediments within the basins.
Finally, ice velocities as well as vertical motion were measured with the ground-based continuous GPS (cGPS) over a 16 month period (details in Supplementary Material, SM-3, http://www.igsoc.org/hyperlink/14j067.pdf).
Results
Crustal structure
Satellite and aeromagnetic data suggest that the Recovery region is a Precambrian basement province, distinct from the adjacent South Pole, Gamburtsev and Ruker terrains (Reference Ferraccioli, Finn, Jordan, Bell, Anderson and DamaskeFerraccioli and others, 2011). Our new modelling of the gravity field reveals a change in crustal thickness between the upslope Recovery Highlands to the east and the Recovery Lakes region (Fig. 2 of Supplementary Material, http://www.igsoc.org/hyperlink/14j067.pdf). We find a good (rms = 12.6) fit between the observed gravity and the forward model of profile 32002 across Lake D (Figs 2 and 3 of Supplementary Material, http://www.igsoc.org/hyperlink/14j067.pdf), with Moho topography calculated assuming Airy isostasy, to derive a change in crustal thickness similar to model results based on the 1960s traverse data across the Lakes A and B region (Reference Bell, Studinger, Shuman, Fahnestock and JoughinBell and others, 2007).
The presence of a crustal boundary offers three of the seven potential controls for ice streaming (Reference Winsborrow, Clark and StokesWinsborrow and others, 2010): a change in geothermal heat flux, a topographic step, and a change in macroscale topographic roughness.
Geothermal heat flux controls the temperature at the base of the ice sheet, influencing the viscosity of the basal ice as well as the location and amount of basal melt that occurs. Changes in crustal thickness are associated with changes in geothermal heat flux (Reference Mareschal and JaupartMareschal and Jaupart, 2013), although without knowledge of the crust's composition we cannot predict the magnitude, nor even the sign of the change. Heterogeneity of shallow geology between the lake basins is suggested by the high Bouguer anomaly over Lake A and the greater magnetic anomaly over Lake C relative to D (Fig. 2 of Supplementary Material, http://www. igsoc.org/hyperlink/14j067.pdf).
All four basins occur near the edge of the crustal boundary, and so will experience the same large-scale changes in geothermal flux associated with this change in crustal thickness. The geological variations inferred between individual lake basins could be associated with further variations in geothermal flux, but the magnitude of these cannot be constrained here. We observe that the difference in geological material underlying Lakes C and D does not result in different ice flow behaviour between the two lakes. We cannot rule out a change in geothermal heat flux associated with the relatively high Bouguer anomaly at Lake A.
Topographic step
The topographic controls on ice streaming are topographic focusing or a topographic step. Topographic focusing occurs where ice is funnelled through a bedrock trough, leading to increased velocity with the increased flux. The main trunk of Recovery Glacier flows through a deep trough, but the region where the velocity increase is first observed is relatively broad (Fig. 1b). A topographic step can influence ice streaming since there will be an increase in strain heating as ice flows over the step, leading to an increase in velocity downstream. A well-defined 800–1000 m topographic step extending for ~ 400 km in a north–south direction separates the elevated Recovery Highlands from the low-lying Recovery Lakes region (Fig. 1b), and is associated with a significant increase in ice thickness, from ~ 2200 m over the Recovery Highlands to >3200 m in the Recovery Lakes region. This topographic step separates the Recovery Highlands from the four lake basins (Fig. 3a and b), although it is closer to the upstream edges of Lakes C and D than the two northern lakes. A change in the regional ice surface slope also occurs at the topographic step (Fig. 1c). The increase in both ice thickness and ice surface slope results in an increased driving stress as the ice flows off the Recovery Highlands into the lake basins (Fig. 2b–e). The driving stress is reduced over the lake basins due to the level ice surface. The topographic step control therefore applies to all four basins, but its effects are expected to be felt most strongly at Lakes C and D.
Basal roughness
Basal roughness affects the friction at the glacier bed, with both the wavelength and orientation of bed topography exerting an influence on flow. Airborne radar reveals a change in basal roughness across the crustal boundary as ice moves from the rugged Highland topography to the smooth lake-region topography. Roughness shifts from on average 60 (dimensionless units) over the Recovery Highlands to 20– 40 over the Recovery Lakes region. This change in roughness is evident across both Lakes C and D, with smooth topography also apparent over Lakes A and B (Fig. 3).
Basin geology
The change from the very rugged topography of the Highlands to the smooth topography of the lake basins could be indicative of sediment infill in the topographic lows. As well as this change in roughness, sedimentary basins can provide a source for lubricating sediment downstream of the basin and affect the routing of subglacial water. Lakes A and B lie at similar depths, ~ 1000 m b.s.l. Lake C is the deepest, at ~ 1100 m, while Lake D is up to 900 m deep. When topography is corrected for removal of the current ice load, Lakes A and B are close to sea level and Lake C is ~ 100 m b.s.l. and could therefore have collected marine sediments in the absence of the ice sheet. Lake D remains ~ 100 m a.s.l. when ice load is removed.
Modelling the gravity anomaly over Lakes A, B and D indicates that the subglacial topography alone is sufficient to produce the observed gravity field and does not suggest an increased thickness of low-density sediments within the basins (Supplementary Material, SM-2, http://www.igsoc.org/hyperlink/14j067.pdf). A high Bouguer anomaly in Lake C, and even higher in the centre of Lake A, suggests that the centre of the basins may in fact be more dense than their margins (Fig. 1 of Supplementary Material, http://www. igsoc.org/hyperlink/14j067.pdf).
Using the Bouguer slab approximation, modelling of airborne gravity with an accuracy of 0.5 mGal can only resolve relative changes in sediment thickness greater than 25 m, and even the higher-resolution (0.1 mGal) ground-based gravity data may miss a thin layer of sediments. The relatively smooth topography of the Recovery Lake region could therefore be the result of a basin fill of <25 m of sediment, or a widespread drape of sediments across the lowlands.
Basal water
Basal water is an important control on ice-streaming behaviour as it strongly influences the friction at the bed and the potential for basal sliding, and can be highly variable, both in its spatial and temporal distribution. There is clear evidence of a robust subglacial network within Recovery Ice Stream from the observations of active subglacial lakes (Reference Smith, Fricker, Joughin and TulaczykSmith and others, 2009; Reference Fricker, Carter, Bell and ScambosFricker and others, 2014) co-located with areas of high ice-flow velocities. All four of the large lake basins are hydraulic minima (Fig. 1 of Supplementary Material, http://www.igsoc.org/hyperlink/14j067.pdf), although A has a smaller downstream hydraulic boundary (~20 m) than C and D (~50 m). Lakes A and B are hydraulically connected at the northern end (Reference LangleyLangley and others, 2011), but a hydraulic boundary exists between them along the southern three profiles (Fig. 1 of Supplementary Material, http://www.igsoc.org/hyperlink/14j067.pdf). Analysis of the ground-based radar data over the northern two lakes has been used to map the distribution of subglacial water in these basins (Langley and others, 2011). Locations with high relative radar brightness and low roughness can be interpreted as water or water-rich environments (Reference Oswald and RobinOswald and Robin, 1973; Reference SiegertSiegert, 2000; Reference Carter, Blankenship, Peters, Young, Holt and MorseCarter and others, 2007; Reference Jacobel, Welch, Osterhouse, Pettersson and GregorJacobel and others, 2009).
Lake A has the clearest indication of subglacial water. The southern third of the lake basin has a smooth and anomalously strong reflectivity, indicating a clean interface between the ice sheet and a basal water body. Intermediate values of the basal reflectivity and roughness over Lake B are indicative of a water-rich environment, but the absence of a uniformly flat reflector indicates there is not a clean lake-like interface.
The airborne radar data over Lakes C and D provide the first constraints on the distribution of water in these basins. Lake C has a 3.5 km long smooth bright reflector (Fig. 3b) in the centre of the basin, similar to reflections interpreted as water in Reference LangleyLangley and others (2011). This bright reflector is located in a 25 km wide region where the brightness residual is high (>0 dB) and roughness is low (<40). This suggests that Lake C has a relatively small 3.5 km wide water body located in a 25 km wide water-rich environment. In contrast, no bright flat reflector was imaged over Lake D. The absence of a bright smooth bed over the topographic minimum (Fig. 3a) indicates that the lake basin is likely dry at present.
Detection of basal water in a radar profile is based on a relative comparison of the reflected power and roughness of the basal interface. Even a thin layer of water will modify the amplitude and form of the reflected pulse due to the high dielectric contrast between ice and water. Since we do not see evidence of a clear water bed reflection in our data, we are unable to resolve the thickness of the water layer with the radar, and rely on gravity measurements for evidence of the water layer thickness. The accuracy of the airborne gravimeter gives a detection limit of ~ 7 m water column thickness, as the gravity signature of water, rather than rock, at the lake bed will be ~ 3.5 times that of low-density sediments. Forward models of the lake basins did not reveal evidence of low-density material in the lake basins, and so provide no evidence for a thick water layer. Thus we infer that while radar surveys identify thin water layers underlying parts of the A, B and C topographic basins, their thickness is on the order of meters, and not hundreds of meters as is the case for Vostok Subglacial Lake.
Data from the two cGPS systems were used to estimate an upper limit on the rate at which the two sites (Recovery B and Rec9) might be experiencing uplift due to filling of the subglacial reservoirs. The results show that nearly all the vertical motion can be attributed to firn compaction at the base of the antenna poles (initially 6.5 and 6.1 m below the surface, respectively). Downward movement, at the rate of 0–2 cm a−1, cannot be ruled out. No attempt was made to account for vertical strain in association with the horizontal movement of the stations (11.93 m a−1, bearing 277°, and 14.12 m a−1, bearing 246°, respectively), but this is probably negligible over the lake basin surfaces.
Refreezing to the base of the ice sheet can occur as the ice sheet flows over a subglacial lake, as for example at Lakes Vostok and Concordia (Reference JouzelJouzel and others, 1999; Reference Bell, Studinger, Tikku, Clarke, Gutner and MeertensBell and others, 2002; Reference Tikku, Bell, Studinger, Clarke, Tabacco and FerraccioliTikku and others, 2005). Reference Bell, Studinger, Shuman, Fahnestock and JoughinBell and others (2007) suggested that accreted ice could facilitate the onset of fast flow in the Recovery region, through the addition of a relatively warm, and thus more readily deformable, layer of basal ice. In the Gamburtsev Mountains (Reference BellBell and others, 2011), refrozen ice and internal layers were imaged at depths greater than 2.5 km as part of the same airborne campaign presented here. Both the airborne and surface radar systems were able to resolve ice thickness in the Recovery region to depths as great as ~ 3.5 km. However, bed returns were generally very weak (Fig. 3), and few internal layers or other structures were imaged below 2.5 km, perhaps indicative of warmer ice and higher attenuation. Thus, it remains ambiguous whether refrozen ice is present in the Recovery Lakes region.
Discussion
The 400 km wide Recovery Lakes region contains many of the mechanisms considered to be potential controls for the onset of fast flow, including a crustal boundary that can support a change in geothermal heat flux, a change in roughness, a topographic step and topographic basins. The presence of water or water-rich environments in three of the basins (A–C), and a dry lake basin (D) allows us to examine the relative roles of water and other factors on the onset of fast flow.
Only Lake A is directly located at the onset of fast flow. Water may be the critical factor for triggering the onset at the downstream edge of Lake A, since it seems to be the most unambiguously lake-like. While all four lakes sit near a crustal boundary and experience a likely change in geothermal heat flux, the local Bouguer anomaly at Lake A (Fig. 2 of Supplementary Material, http://www.igsoc.org/hyperlink/14j067.pdf) is twice as large as other local variations, and may be associated with further variations in geothermal heat flux, which could continue beyond the lake boundary along the surveyed line. Increased water production in the vicinity of Lake A would explain the observed higher water content of the Lake A basin, but this is not well constrained.
Lake D has a topographic step, a change in geothermal flux, a change in roughness and possible topographic forcing, but there is no change in velocity for >150 km downstream. The absence of water in Lake D is a likely candidate to explain why fast flow does not occur at the downstream edge of this dry lake basin.
Lakes C and B both have water or water-rich environments, a step change in roughness, and a likely change in geothermal flux, yet are not directly associated with streaming onset. While Lake A might experience greater water production in the presence of a potential increase in geothermal heat, lakes A, B and C all show clear signs of the presence of water. The only significant difference, beyond this, between Lakes A and B/C is the topography at the downstream edge of the lakes. Lake A has a gently sloping margin, in contrast to the steeper edges of B and C. While the limited coverage of ice thickness data from the region prevents a detailed analysis of hydrologic pathways, along our survey lines we see that the downstream margin of Lake A presents a lower hydraulic barrier than the margins at either Lake C or B (along the southern three profiles). We suggest that the bounding topographic ridges of C and B prevent water from moving out of these subglacial lakes. This is significant since we observe that the fastest ice flow occurs in the areas with active basal drainage systems, as indicated by the presence of the active lakes (e.g. Reference Smith, Fricker, Joughin and TulaczykSmith and others, 2009) (Fig. 1).
The cGPS measurements show that, over the 16 month observation period, there was very little surface elevation movement on either of the surveyed lakes (Lake B and the smaller lake to the north; Fig. 1) that might indicate filling or draining (Fig. 5 of Supplementary Material, http://www. igsoc.org/hyperlink/14j067.pdf). Alternatively, the observations can be explained by a constant flux of water moving through these systems. Since Lake B is hydraulically connected to Lake A at the northern end (Reference LangleyLangley and others, 2011; Fig. 1 of Supplementary Material, http://www. igsoc.org/hyperlink/14j067.pdf) we would expect surface variations linked to basal water to be consistent between these two. The total amount of water in the system cannot be determined here; however, we believe the critical factor is the presence of water and its ability to overcome hydro-logical barriers to move through the system.
Water in subglacial lakes can be important in initiating fast flow, but if the lake is steep-sided on the downstream edge, water is effectively prevented from flowing along this path, suppressing the onset of fast flow. This is supported by the difference in fast-flow onset from the Recovery Lakes and also from the steep-sided tectonically controlled lakes (e.g. Vostok Subglacial Lake or 90°E Lake) that do not appear to foster the onset of fast flow. Though refreezing of water to the base of the ice sheet may influence the ice flow out of the Recovery Lakes, the inability of the radar systems to image the deeper internal structures leaves the role of refrozen lake water unresolved. The onset of fast flow at the downstream margin of Lake A is evidence that water stored in broader basins with gentle bounding topography is more likely to be connected to the downstream subglacial hydrologic network and more likely to foster the onset of fast flow.
Conclusions
Recovery Ice Stream extends far inland, terminating along its northernmost edge in the Recovery Lakes. New geophysical data allow us to describe the physical setting of this upper catchment area, which fosters the onset of Recovery Ice Stream. The region is characterized by a crustal boundary, a change in bed roughness, a topographic step and four topographic basins (A–D). A crustal boundary separates the elevated Recovery Highlands, underlain by thicker crust to the east, and the low-lying smooth Recovery Lakes region, underlain by thinner crust to the west. This crustal boundary controls both a 500–1000 m high topographic step and a regional change in roughness. Three of the topographic basins in the Recovery Lakes region contain water (Lakes A–C). In Lakes B and C the subglacial water is located in basins with sharp downstream ridges, in contrast to the gradual slopes on the downstream margin of Lake A. The fastest-flowing branch of the ice stream reaches the margin of Lake A, the only lake basin with a shallow slope that may allow the water to escape. The presence of multiple potential control mechanisms along the four Recovery Lakes region allows us to establish that basal water is a dominant factor for the onset of fast flow but only if it is stored in a shallow-sided basin where it can lubricate the flow downstream. Relatively minor topographic barriers appear to inhibit the onset of streaming out of Lakes B and C. Other proposed controls (e.g. topographic steps, changes in bed roughness, changes in geothermal flux, and lubricating sediments) appear to have a lesser influence.
Acknowledgements
We acknowledge all members of the Norwegian–US IPY traverse and the AGAP field teams. The ground-based work was carried out under the umbrella of the International Trans-Antarctic Scientific Expedition (ITASE)–Ice Divide of East Antarctica (IDEA) within the framework of IPY project No. 152 funded by the Norwegian Polar Institute (NPI), the Research Council of Norway and the US National Science Foundation (NSF). This work is also a contribution to ITASE. K. Langley was supported in part by the Center for Ice, Climate and Ecosystems (ICE) of the NPI. We acknowledge the seven nations involved in the AGAP IPY effort for their logistical, financial and intellectual support. Specifically the US Antarctic Program of the NSF provided support for the logistics, development of the instrumentation and analysis of the data. The UK Natural Environment Research Council (NERC)/British Antarctic Survey (BAS) provided extensive support for deep-field logistics, data collection and analysis. The Federal Institute for Geosciences and Resources, Germany (BGR), and the Polar Research Institute of China provided invaluable support to the program. K. Langley's visit was supported by the Lamont–Doherty Marie Tharp Fellowship.