Analogy to deglaciated terrain

Deglaciated terrains can never be perfect analogs for subglacial conditions, both because of differences in conditions during glaciation, and because the imprints of deglaciation and subsequent changes are lacking beneath active glaciers. Nonetheless, experience shows that knowledge gained from glacial geology informs glaciology (e.g. Boulton, Reference Boulton1976; Stokes and others, Reference Stokes, Margold and Creyts2016).

Deglaciated terrains commonly expose stoss-side rock with lee side till or other sediment, at many scales (e.g. Evans and Hansom, Reference Evans and Hansom1996; Ives and Iverson, Reference Ives and Iverson2019). Figure 2a shows the stoss side of a bump, ~6 to 7 m tall, on Danmark Island, east Greenland. The stoss side of the bump is visible, and ice went up this slope away from the camera, striating and polishing (rockfall from the face has occurred postglacially). The lee side of this bump is soft sediment, probably till, filled almost to the level of the top of the bump. Figure 2b shows a smaller-scale bedrock bump that was exposed within the last couple of years in front of the rapidly retreating Sólheimajökull in Iceland. Although not shown in the photo, the lee side of this bump has a slope gentler than the stoss side and is made of sediment, indicating sediment accumulation there.

Fig. 2. (a) A stoss-side bedrock exposure in till fields on Danmark Island in east Greenland. Inferred ice flow was into and slightly towards the left of the page. (b) Stoss side of a bedrock bump within a till field in front of Sólheimajökull in Iceland. The ice flow was into the page. Person kneeling down is A. Muto. Both photos were taken by R. Alley.

In light of such widespread occurrence of stoss-side bedrock and lee side sediment, it is reasonable to surmise that similar conditions will exist in the subglacial environment.

Till continuity

The data of M2019 show regions of seismically thick till with the acoustic impedance less than that for ice, indicating high porosity and high basal-water pressure (e.g. Peters and others, Reference Peters2006). Under such conditions, prior work (some of which we summarize below) suggests that the till is deforming, but primarily in a narrow zone close to the base of the ice, and that increasing water supply will decrease till deformation by decoupling the ice from the till.

Thwaites Glacier is within the West Antarctic Rift System and is underlain by thin, stretched crust, likely resulting in elevated geothermal flux (Damiani and others, Reference Damiani, Jordan, Ferraccioli, Young and Blankenship2014; Schroeder and others, Reference Schroeder, Blankenship, Young and Quartini2014), and there is abundant subglacial water supply (Joughin and others, Reference Joughin2009; Schroeder and others, Reference Schroeder, Blankenship, Young and Quartini2014; Smith and others, Reference Smith, Gourmelen, Huth and Joughin2017). Seismic data of M2019 indicate a thawed bed with abundant water, consistent with these studies.

On Whillans Ice Stream (formerly Ice Stream B), boreholes near where seismic measurements earlier indicated water-saturated deforming till at the bed (Blankenship and others, Reference Blankenship, Bentley, Rooney and Alley1986, Reference Blankenship, Bentley, Rooney and Alley1987) showed water pressures within 2% of flotation, with a few measurements above flotation (Engelhardt and Kamb, Reference Engelhardt and Kamb1997; Kamb, Reference Kamb, Alley and Bindschadler2001). Below one of the boreholes, till deformation was limited to a 3–25 cm layer at the top of the till package, and accounted for only 17% of the total basal motion (Engelhardt and Kamb, Reference Engelhardt and Kamb1998; Kamb, Reference Kamb, Alley and Bindschadler2001). It should be borne in mind, however, that this is a single observation and some large water-pressure fluctuations (up to 1 MPa) were recorded during the observational period (Engelhardt and Kamb, Reference Engelhardt and Kamb1998; Alley, Reference Alley2000), perhaps helping maintain dilatancy to greater depth in the till to produce the seismically thick soft layer (Leeman and others, Reference Leeman, Valdez, Alley, Anandakrishnan and Saffer2016). Adding water from the boreholes floated the ice off the bed (Kamb, Reference Kamb, Alley and Bindschadler2001), thus reducing deformation. The weak fabrics within the sediments recovered from beneath Subglacial Lake Whillans, located ~200 km downstream, suggest that the till deformation was within the uppermost 10 cm of the till layer (Hodson and others, Reference Hodson, Powell, Brachfeld, Tulaczyk and Scherer2016), supporting the earlier observations.

Similar relations between the basal-water pressure and ice-till coupling are observed beneath mountain glaciers. Transient observations of water pressure in boreholes and shear strain rate in till beneath Trapridge Glacier in Canada (Fischer and Clarke, Reference Fischer and Clarke2001; Kavanaugh and Clarke, Reference Kavanaugh and Clarke2006) and Storglaciären in Sweden (Iverson and others, Reference Iverson, Hanson, Hooke and Jansson1995) showed reduced shear strain rate when the water pressure rose. Even negative shear strain rates were recorded during some water-pressure peaks (Iverson and others, Reference Iverson, Hanson, Hooke and Jansson1995; Fischer and Clarke, Reference Fischer and Clarke2001), indicating that the till decoupled from the bed locally and stopped shearing under high water pressure (low effective pressure), responding elastically to reduced shear stress (Iverson and others, Reference Iverson, Hanson, Hooke and Jansson1995, Reference Iverson, Baker, Hooke, Hanson and Jansson1999). These changes beneath small alpine glaciers mainly result from water input from the glacier surface, which does not occur on Whillans Ice Stream nor Thwaites Glacier. Nevertheless, reduced ice-till coupling under higher basal-water pressure was consistently recorded and is physically almost inevitable.

We hypothesize that this time-varying behavior also applies to spatial variations along flow in our survey region. As discussed above, increase in water flux is observed to cause a rise in the basal-water pressure, increasing the thickness or area of linked cavities or other features that store and transmit water to balance the greater water flux, and in turn leading to a larger mean thickness of water separating ice and till (Iverson, Reference Iverson1999; Iverson and others, Reference Iverson2007; see review by Alley, Reference Alley1996). In turn, this may focus stress on a few large clasts that plough the upper part of the till, rather than the ice coupling more widely and driving deeper deformation (Iverson, Reference Iverson1999; Iverson and others, Reference Iverson2007). Therefore, areas of greater water convergence should exhibit greater decoupling between ice and till, and thus less till flux from deformation. This implies that regions of along-ice flow convergence of water have small till flux, whereas along-ice flow divergence of water favors greater till flux. Transitions from water convergence to divergence along ice flow then should increase potential sediment flux, leading to till evacuation, exposing bedrock. A thin deforming layer from soft-bed regions, with deformation, largely occurring over a thickness of order 0.1 m and only where ice and till are not separated by water, would then thin as it was carried into the hard-bed regions, where it would deform more rapidly. Such a layer would be unlikely to bury bedrock topography, and thus likely would be discontinuous in space and perhaps also in time.

We calculated the glaciological hydraulic potential (ϕ) along the main M2019 L-line (Fig. 1), assuming ϕ depends on surface and bed elevations, and that the basal-water pressure is equal to the ice overburden pressure (Shreve, Reference Shreve1972),

(1)$$\phi \, = \,\; \rho _{\rm w}gz_{\rm b}\, + \,\; \rho _{\rm i}g\,(z_{\rm s}-z_{\rm b})$$

where ρ _w and ρ _i are the densities of water and ice, respectively, g is the gravitational acceleration, and z _s and z _b are the surface and bed elevations, respectively. Surface elevation (z _s) is from the differential GPS data collected concurrently with the seismic data, and bed elevation (z _b) is from the M2019 seismic data. We then calculated the gradient of the hydraulic potential (dϕ/dx, the first derivative of the hydraulic potential) and its divergence (d ²ϕ/dx ², the second derivative of the hydraulic potential) along the line to find locations where the subglacial water is likely to converge (positive d ²ϕ/dx ²) or diverge (negative d ²ϕ/dx ²). The result is shown in Figure 3, with the cross plot of the acoustic impedance (Z _b) and d ²ϕ/dx ² in Figure 4.

Fig. 3. (a) Surface (blue solid line, left vertical axis) and bed (red solid line, right vertical axis) elevation profiles with the bed-elevation uncertainty (36 m) in red dotted lines. Note that the scale is different for the two profiles and the uncertainty of the surface elevation (10 cm) is negligible. (b) Glaciological hydraulic potential (ϕ). (c) Hydraulic-potential gradient (dϕ/dx). (d) Divergence of the hydraulic-potential gradient (d ²ϕ/dx ²). (e) The bed acoustic impedance (Z _b) and interpreted bed type (same as Fig. 1c).

Fig. 4. Cross plot of the acoustic impedance (Z _b) and the divergence of the hydraulic-potential gradient (d ²ϕ/dx ²). The color scale indicates the location of the acoustic-impedance measurements along the seismic survey line. Spearman's rank correlation coefficient (ρ) of Z _b and d ²ϕ/dx ² and its p-value are shown.

The pattern of water convergence/divergence and the bed types show a reasonable match with our expectations based on the surface and bed elevations and our current knowledge of the basal slip (e.g. Cuffey and Paterson, Reference Cuffey and Paterson2010; Iverson, Reference Iverson2010), supporting our hypothesis above. In the subglacial highlands (Figs 1a and 3a), d ²ϕ/dx ² fluctuates rapidly over several hundred meters to a kilometer along flow, as expected from the more variable surface and bed topographies (Fig. 3d). Negative d ²ϕ/dx ² are found over hard-bedded stoss sides (e.g. 23.5–24.2 km, 28.5–29.1 km and 33.9–34.5 km), seen as a cluster of points with higher Z _b and negative d ²ϕ/dx ² in the cross plot (Fig. 4). Positive d ²ϕ/dx ² mostly corresponds to soft-bedded lee sides (e.g. 19.5–22 km and 25.5–26.5 km). In the upstream soft-bedded basin, the magnitude of d ²ϕ/dx ² is smaller but mostly positive, indicating water convergence, with some of the local maxima corresponding to locations where seismic data indicated water ponding (4 and 11.5 km). The Spearman's rank correlation coefficient (ρ) of the Z _b and d ²ϕ/dx ² is −0.48 with the p-value close to 0 (Fig. 4), indicating a weak but significant negative correlation, further supporting our expectation that the hard (soft) bed is associated with water divergence (convergence). We note, however, that the uncertainties of d ²ϕ/dx ² include both positive and negative values across this upstream region, suggesting that the correlation of water convergence/divergence with the bed type over the basin may not be as robust as in the downstream highlands.

The acoustic-impedance data were collected at sites spaced mostly ~480 m apart and have the Fresnel-zone width of ~365 m. However, there are data gaps up to ~2-km long, arising because of the relatively steep bed slopes where incidence angles of the bed reflections exceeded 10^° and the normal-incidence approximation does not hold. This introduces some uncertainty to the interpretation (e.g. 23.2, 28.3 and 33.6 km). We also find regions that are not consistent with our hypothesis (e.g. 13.3–17 km and 29.5–31 km) where d ²ϕ/dx ² is negative, indicating water divergence although the seismic data showed soft bed. We cannot tell whether this arises from inadequacies in data, in our assumptions (e.g. out-of-plane water flow), or whether additional processes are active.

Despite these data shortcomings and some mismatches, our results overall suggest that ice will couple more strongly to till on stoss sides than on lee sides, so more till can be carried across stoss sides than is supplied from lee sides. Unless rapid erosion occurs to generate more till (which we discount in part because the stoss sides are still there and have not been worn away), the till then must thin from lee to stoss sides, making it less able to bury small-scale bumps on the stoss sides and favoring a hard-bedded sliding law on the stoss sides alternating with the soft-bedded sliding law on lee sides.

Basal shear stress

If a thin, deforming till layer was present on stoss sides, it could bury bumps at the sub-meter scale that may be most important in limiting basal sliding (Weertman, Reference Weertman1957) and prevent friction between bedrock and rocks carried in basal ice. In such a case, we would expect relatively low dynamic drag at the bed. In contrast, bedrock not covered by till can support higher dynamic drag.

We performed a simple inversion for the basal shear stress along the M2019 L-line, which is aligned close to the ice flow direction, using observed surface and bed elevations and the surface speed. We used the Pennsylvania State University 2-D higher-order, finite element model (PSU2D, Parizek and others, Reference Parizek, Alley, Dupont, Walker and Anandakrishnan2010; Koellner and others, Reference Koellner, Parizek, Alley, Muto and Holschuh2019) as the forward model to simulate outlet glacier flow. Within PSU2D, the basal-slip law is represented by a power law:

(2)$$\tau _{\rm b} = \; B_{\rm b}u\lpar b \rpar^{\textstyle{1 \over m}}$$

where τ _b and B _b are the shear stress and drag coefficient, respectively, at the basal interface. The bed exponent m was held constant across the domain with values of either 1 (linear viscous) or 3 (weakly nonlinear) to represent hard bed and 8 (effectively plastic) to represent soft bed. Total basal traction along the ice/bed interface is composed of both form drag arising from variations in bed elevation and dynamic drag associated with the basal shear stress that is supported by the subglacial material.

Surface elevation used here is from the Airborne Topographic Mapper (ATM; Studinger, Reference Studinger2014, updated, 2018) and bed elevation is from the Multi-channel Coherent Radar Depth Sounder (MCoRDS; Paden and others, Reference Paden, Li, Leuschen, Rodriguez-Morales and Hale2010, updated, 2018) of NASA's Operation IceBridge. A survey line along the ice flow, including over the M2019 L-line, was flown on 11 November 2011. We used these OIB surface and bed elevation data here rather than in situ data from the seismic survey as was done for the hydraulic-potential calculation in order to minimize boundary effects by extending the model domain ~85 km upstream and ~5 km downstream of the ~40 km seismic line. For the surface speed, we used the MEaSUREs InSAR-based velocity (Rignot and others, Reference Rignot, Mouginot and Scheuchl2017) interpolated along the OIB data. All of these datasets were interpolated at a 250-m interval along the flowline. This is spatially coarse compared to the individual linked cavities or other features generally envisioned to transmit basal water (e.g. Iverson, Reference Iverson1999), so the inversion provides a spatial average across such sub-meter to few-meter features.

We inverted for the basal drag by determining the pattern of the basal drag coefficient (B _b) that reduces the misfit between observed and modeled surface speeds. For each rheology tested, we first looked for a uniform B _b value that gives the approximate mean observed surface speed (~125 m a⁻¹) within the seismic-survey subdomain. We then iteratively adjusted the B _b field along the entire flowline, followed by additional fine-tuning iterations along the subdomain such that the modeled surface speed closely approximated the observed values along the seismic line (within ~7% on average, with misfits as low as ~0.004% and as high as ~24% across the broad region (6–14 km Figs 3a and 5a) of surface-slope reversal). We thereby recover variations of interest in B _b and subsequently τ _b.

Fig. 5. (a) Observed (red solid line) and modeled (blue, black and orange solid lines) surface speeds. Note that colors for different m values apply to panels b and c. (b) Basal drag coefficient (B _b). (c) Basal shear stress (τ _b). (d) Driving stress (τ _d). (e) The bed acoustic impedance (Z _b) and bed type (same as Fig. 1c).

The observed and modeled surface speeds, the resulting basal drag coefficient (B _b), and the calculated basal shear stress (τ _b) are displayed for each basal-slip law (m) in Figures 5a–c, respectively. We also plot Z _b and τ _b for each seismic-data location as cross plots for each basal-slip law (Fig. 6). At the broad scale for each m, τ _b shows the expected pattern; basal shear stress is low in the soft-bedded basin, high overall in the highlands with mixed-bed conditions, and increases when bumps are encountered, and Z _b and τ _b have weak, but positive correlation (Fig. 6). Furthermore, τ _b varies more (less) with sharper (gentler) transitions between low and high values for lower (higher) m, reflecting the nature of the nearly viscous (nearly plastic) slip law to concentrate stresses locally (distribute stresses over a larger distance) (Parizek and others, Reference Parizek2013; Koellner and others, Reference Koellner, Parizek, Alley, Muto and Holschuh2019).

Fig. 6. Cross plots of the acoustic impedance (Z _b) and the basal shear stress (τ _b) for different bed exponent: (a) m = 1, (b) m = 3 and (c) m = 8. The color scale indicates the location of the acoustic-impedance measurements along the seismic survey line. The Spearman's rank correlation coefficient (ρ) of Z _b and τ _b and its p-value for each case of m are shown.

Within the basin and the initial upslope into the highlands (between 4 and 16.5 km; Fig. 3a), the basal shear stress is essentially zero (Fig. 5c) where the seismic data showed continuous soft bed with a few locations with ponded water (Fig. 5e). Due to positive surface slopes (negative driving stresses; Fig. 5d) across this broad zone, PSU2D underestimates surface speed over this region despite the lack of dynamic drag. This warrants further investigation of transverse flow effects.

Just prior to entering this soft zone, τ _b is elevated within a region where local driving stress reaches ~270 kPa (Fig. 5d) as ice flows over a ~5-km-long, ~45-m-high bump that begins ~2 km upstream of the seismic line. Relatively high basal shear stress here is consistent with the higher acoustic impedance values among the soft-bedded regions, suggestive of deforming but likely lower-porosity soft bed.

In the highlands, sharp increases in τ _b correspond to seismically hard, stoss sides of bumps (e.g. 18.5–19, and 23.5–24 and 28.5–29 km). Also, the longest stretch of high driving stress and τ _b near the downstream end coincides with the longest section of seismically hard bed between 32 and 35.5 km with relatively high acoustic impedance values (except a long data gap at ~33–34 km), supporting our hypothesis. However, there are localized sections such as 19.5–22 km, 25–26.5 km and 30–31 km where τ _b remains high on the lee side of bumps with soft beds. As previously discussed, these may arise from data inadequacies, out-of-plane effects, additional processes or some combination of these; however, we cannot tell at this point which of these possibilities is at play.