Physical Conditions of Fast Glacier Flow: 2. Variable Extent of Anisotropic Ice and Soft Basal Sediment From Seismic Reflection Data Acquired on Store Glacier, West Greenland
Abstract
Outlet glaciers of the Greenland Ice Sheet transport ice from the interior to the ocean and contribute directly to sea level rise because discharge and ablation often exceed the accumulation. To develop a better understanding of these fast-flowing glaciers, we investigate the basal conditions of Store Glacier, a large outlet glacier flowing into Uummannaq Fjord in west Greenland. We use two crossing seismic profiles acquired near the centerline, 30 km upstream of the calving front, to interpret the physical nature of the ice and bed. We identify one notably englacial and two notably subglacial seismic reflections on both profiles. The englacial reflection represents a change in crystal orientation fabric, interpreted to be the Holocene-Wisconsin transition. From Amplitude-Versus-Angle (AVA) analysis we infer that the deepest ∼80 m of ice of the parallel-flow profile below this reflection is anisotropic with an enhancement of simple shear of ∼2. The ice is underlain by ∼45 m of unconsolidated sediments, below which there is a strong reflection caused by the transition to consolidated sediments. In the across-flow profile subglacial properties vary over small scale and the polarity of the ice-bed reflection switches from positive to negative. We interpret these as patches of different basal slipperiness associated with variable amounts of water. Our results illustrate variability in basal properties, and hence ice-bed coupling, at a spatial scale of ∼100 m, highlighting the need for direct observations of the bed to improve the basal boundary conditions in ice-dynamic models.
Key Points
- Two high-resolution seismic reflection profiles were acquired 30 km upstream of the calving front at the center flow line of Store Glacier, a fast-flowing tidewater glacier draining the western sector of the Greenland ice sheet
- Analysis reveals an 80 m thick layer of anisotropic, horizontally easily deformable basal ice, overlying 45 m unconsolidated sediments which rest on a sequence of hard consolidated sediments
- Spatial variability of basal anisotropic ice and subglacial material imply different subglacial deformation mechanisms, that is, Coulomb-type of plastic deformation and a Weertman-type of sliding
1 Introduction
Mass loss from the Greenland Ice Sheet (GrIS) consists of two main components: meltwater runoff and ice discharge into the surrounding ocean (e.g., Fürst et al., 2015). Since the late 1990s, Greenland has lost ice at an increasing rate (Bevan et al., 2012; Hanna et al., 2013; Joughin et al., 2012; Shepherd et al., 2012). The most recent estimate from 2009 to 2012 is a mass loss of 378 Gt/a equivalent to an estimated sea level rise (SLR) of 1.1 mm/a over the period 2009–2012 (Enderlin et al., 2014; Van den Broeke et al., 2016), which makes the GrIS the single largest contributor of the global cryosphere to SLR. Approximately half of this ice loss is attributed to dynamic thinning with the other half explained by surface melting and runoff (Csatho et al., 2014; Rignot & Mouginot, 2012; Van den Broeke et al., 2009). Whereas meltwater production and runoff is well represented in global sea level prediction (Intergovernmental Panel on Climate Change, 2013), the contribution to SLR resulting from ice discharge and dynamic thinning is still relatively poorly understood (e.g., Csatho et al., 2014). Several possible mechanisms have been suggested as to the cause of increased dynamic thinning. They can generally be divided into two end-members: A warmer atmosphere leading to increased surface melt which partly drains to the base, thereby enhancing sliding, or a warmer ocean interacting with the ice sheet's marine-terminating glaciers, causing melt, thereby reducing the back force and increasing outlet ice flow. Both end-members cause an increase in outlet glacier flow leading to a lowering of the ice surface resulting in an increase in the surface slope. This, in turn, increases the driving force of outlet glaciers.
An important boundary condition for ice discharge and dynamic thinning, regardless of which end-member is more important, is the nature of the subglacial material. It is especially important to establish whether ice flows over hard bedrock or water saturated sediments, and whether sliding at the bed occurs in a strict sense by deformation of ice or sediment, or a combination of both.
There is abundant evidence that fast outlet glaciers and ice streams in Antarctica are underlain by soft sediments (e.g., Alley et al., 1986; Anandakrishnan et al., 1998; Anandakrishnan, 2003; Blankenship et al., 1986; Smith & Murray, 2008; Smith et al., 2007, 2013). Thick saturated till has been identified on Antarctic ice streams giving little resistance, thus allowing fast ice flow. Routing of subglacial water is thought to be the cause of sticky spots resisting ice flow (Winberry et al., 2014), so water content in subglacial sediments regulates the basal friction and thus the sliding velocity.
It has long been thought that Greenland's outlet glaciers predominantly slide over hard bedrock. However, more recent evidence has revealed the presence of sediments beneath several areas of the GrIS (Walter et al., 2014). Christianson et al. (2014) and Vallelonga et al. (2014) recently identified dilatant till beneath the onset of the Northeast Greenland Ice Stream, demonstrating that the single largest ice stream in Greenland has soft basal conditions that are very similar to those observed more frequently beneath Antarctic ice streams. In west Greenland glacial sediments are widespread on the continental shelf (Dowdeswell et al., 2014; Hogan et al., 2012) and are also likely to be present subglacially. Dow et al. (2013) found highly porous sediments under Russell Glacier in Southwest Greenland, the same place where van de Wal et al. (2015) found seasonality in ice flow caused by water pressure build up in and release from subglacial sediments.
To identify and characterize the basal mechanical and hydrological conditions at a large, fast-flowing marine-terminating outlet glacier, we collected seismic data along two perpendicular profiles on the central flow line of Store Glacier in west Greenland.
2 Data and Methods
2.1 Field Site
Store Glacier is the third largest tidewater glacier on the west coast of Greenland (Chauché et al., 2014) with an outlet velocity of 5,300 m/a and a seasonal ice velocity variation of approximately 500–700 m/a at the terminus (Howat et al., 2010; Todd & Christoffersen, 2014). It drains an area of 35,100 km2, has an ablation area of 5,200 km2, and discharges approximately 12 km3 of ice and 2–3 km3 of meltwater in Uummannaq Fjord annually. A 450 m overdeepened trough in the fjord gives Atlantic Water access to its ice-ocean interface (Chauché et al., 2014). The seasonality of the ice flow of Store Glacier has been linked to ice-ocean interaction (Howat et al., 2010; Todd & Christoffersen, 2014). However, very little is known about basal conditions and the meltwater runoff that largely occurs subglacially.
2.2 Survey Area
The survey area is located in the ablation zone, 30 km upstream of the calving front of Store Glacier at ∼900 m elevation (Figure 1). The glacier flows here in the direction 262° relative to True North (T), at a rate of ∼600 m/a on the eastern (up-flow) side, increasing to ∼700 m/a toward the western (down-flow) side. The 2 km2 survey area has a densely crevassed, but nevertheless accessible surface, and provides an opportunity to investigate the glacial and subglacial conditions beneath the fast-moving ice of a marine-terminating outlet glacier in an otherwise inaccessible area. Two high-resolution seismic profiles were collected in the summer of 2014. At that time the ice surface was characterized by ice, abundant drainage channels, melt ponds, moulins, and water-filled crevasses orientated perpendicular to the ice flow direction. The ice surface had some meter scale undulation, a 100 m lowering in ice flow direction (maximum surface slope of 4°), and a 30 m depression in the center of the crossline (maximum surface slope of 2°).
2.3 Seismic Data Sets
We recorded two data sets: A profiling data set to identify the substructure of the ice and subglacial material and an Amplitude-Versus-Angle (AVA) data set to identity the subsurface materials. Each data set was processed differently.
2.3.1 Profiling
We recorded two crossing seismic profiles. The first was a 2010 m along-profile, Line 1, aligned parallel to the ice flow (direction 262°); the second a 1,348 m across-profile, Line 2, aligned transverse to ice flow (direction 325°). We recorded twofold seismic data using a 300 m snow streamer consisting of 96 gimballed 30 Hz geophones (vertical P wave sensors). The shot point (SP) spacing was either 150 m or 75 m. The seismic source for each shot was a 400 g dynamite charge placed in an ∼2 m deep borehole. As the surface comprised solid ice, there was no loss of elastic energy due to firn compression or diving waves. Data were recorded on four seismographs mounted on a Nansen sled that also towed the snow streamer. The streamer and sled were manually hauled across the glacier surface, but maneuverability was limited, particularly through crevassed fields. To increase the length of the seismic profiles, we recorded additional shots (SP 1 to 11), starting at 1,500 to 0 m offset, decreasing in 150 m increments, while the streamer was maintained in its initial starting position at SP 11 (Figure 2). We then moved streamer and shot together, keeping an offset of 22 m between the two and a shot spacing of 75 m until ice surface conditions became too demanding (shaded area, SP 12 to 22). The offset operation was then repeated, maintaining the streamer in its final position and recording additional shots in steps of 150 m increasing offset (SP 23 to 26). The position of each SP was surveyed to a horizontal and vertical accuracy of 0.1 m using a Trimble R7 GPS postprocessed against correction data from Trimble NetRS base station permanently deployed on solid bedrock adjacent the glacier front. A summary is given in Table 1.
SP | Offset (m) | SP interval (m) | Streamer position |
---|---|---|---|
1–11 | 1,500–0 | 150 | SP 11 |
12–22 | 22 | 75 | SP 12–SP 22 |
23–26 | 150–600 | 150 | SP 22 |
As our data were twofold processing was done in the shot domain. We processed the profiling data sets using land-based techniques but applied a few modifications caused by the specific setting (heavily crevassed ice surface). We removed noisy traces and applied manual static corrections. We used spiking deconvolution to compress the 10 ms long source wavelet and to suppress the ghost (arriving 1 to 2 ms after the primary source wavelet). We applied spatial frequency filtering (FK) to remove crevasse-generated linear moveout noise, band-pass filtering, stacking, and a poststack Kirchhoff migration. The strong vertical velocity inversions at the ice base and lateral amplitude contrast caused by highly variable attenuation of the receivers causes smiles in the migrated stacks which is why we show both the filtered stacks and migrated stacks are shown in Figure 3. We refer to these as (migrated) profiles.
2.3.2 AVA Analysis
2.4 The Reflection Coefficient at Normal Incidence
3 Results
The seismic data (Figure 3) clearly show different seismic events each with individual characteristics. The data contain various types of noise, related to the heavily crevassed surface and the summertime glacial conditions. We distinguish coherent low-frequency noise with linear moveout, noisy channels, varying frequency content in the traces caused by varying attenuation, and static variability between traces. The linear moveout noise is crevasse generated, reflecting the direct wave caused by the source as the effect is absent on noise records (i.e., recordings without a detonated shot). Noisy channels are mainly caused by poor contact of the geophones with the ice (e.g., some were occasionally hanging in crevasses) or picking up ambient noise such as running melt water. Lateral changes in attenuation are most likely caused by (water-filled) crevasses through which the source wavelet travels. This also caused varying travel times of reflections, leading to static variability between channels. Despite the high noise level several strong reflections can be clearly identified from the seismic profiles.
3.1 Identified Reflections
In both profiles we identify three important reflections, hereafter named R280, R327, and R358 after their Two Way Traveltime (TWT) relative to the starting position of the streamer (CMP 870 at the along-profile). The reflections characterize the englacial, basal, and subglacial conditions and distinguish four different media.
Reflection R280 is strongest in the central part of the along-profile from CMP 555 to CMP 1452 (Figure3a). The reflection has bed conformity and long spatial wavelength variation in the flow direction but not across-flow. The polarity of the top reflection is positive throughout the along-profile. The reflection lies at the top of an ∼20 ms long series that consists of more than one reflection and fades out around CMP 1560 on the western side. At the across-profile R280 forms an almost symmetric apparent syncline or fold with a hingeline at CMP 500 (Figure 3c). In the migrated profile (Figure 3e) the hingeline cannot be tracked as it disappears in the smiles of a deeper event. The polarity and wavelet of R280 is similar on both profiles: It consists of a 20 ms long reflection series starting with small positive amplitude followed by a larger negative amplitude.
Reflection R327 is the uppermost reflection of a series of events, forming a seismically stratified sequence, approximately 30 to 40 ms long (Figure 3a). It is most clearly visible in the central part of the along-profile from CMP 685 to CMP 1297, where we recorded with a fixed offset. The reflection is discontinuous and varies in strength along-flow. The reflection fades out at the start and end of the profile where the offsets are largest (i.e., eastern side, CMP 421–CMP 685 especially between CMP 486 and CMP 583 and beyond CMP 1350 on the western side). R327 can be tracked in the across-profile but only at the crosspoint area (Figure 3c). The top of the stratification, R327, fades out on the southern side around CMP 165 and terminates sharply on the northern side at CMP 382.
Reflection R358 is the deepest notable event recorded in the along-profile and is particularly pronounced at larger offsets (Figure 3a, CMP 424–CMP 685). It appears smooth and horizontal except on the western side beyond CMP 1250 (crossing) where it has a more pronounced topography. This reflection is stronger than both R280 and R327 and mostly has a positive polarity. At larger offsets, that is, before CMP 685 and beyond CMP 1452, the resolution disappears due to increased attenuation. At smaller offsets, however, stratification is visible. At the central part of the along-profile, the reflection is not always continuous and it is difficult to discern the polarity. In the across-profile R358 shows a more pronounced topography but generally dips to the north. At the crossing at CMP 300 of the across-profile (Figures 3c and 3e), reflection R358 forms a local depression. On the southern side the polarity of reflection coefficient R is positive but on the northern side, around CMP 450, R becomes negative (Figure 3d). This part with a negative reflection coefficient (CMP 500–CMP 50) causes a strong smile in the migrated profile (Figure 3e).
Overall, the along-profile reflections are horizontal to subhorizontal and aligned parallel to each other (Figure 3a), whereas the across-profile reflections show greater roughness at the scale of ∼100 m (Figures 3c and 3e).
3.2 Velocity Analysis and TWT Conversions
For a velocity analysis we collected an additional large offset data set (0–900 m) on the along-profile at the crosspoint (CMP 1201–CMP 1297). By using Dix's method (Dix, 1955) over a wide range of offsets, we retrieved the root-mean-square velocity (Vrms) and the interval velocity (Vint) of the media overlying the three identified reflections. The resulting Vrms varied within 0.5–1.5%, depending on the considered offset interval. We prescribe this variation as the uncertainty. A precondition of Dix's method is that the reflections are horizontal, which is approximately the case for the top two reflections, R280 and R327. Reflection R358 slopes ∼6∘ causing an overestimation of Vrms which we have corrected for (Dix, 1955). From Vrms we derived the depths z and interval velocities Vint for the layer above the reflections R280, R327, and R358 (Table 2). The calculated Vint represents the average value Vp for the whole depth interval considered between two reflections. Between 0 and 528 ± 8 m depth, Vint=3770 ± 60 m/s, between 528 ± 8 m and 611 ± 5 m depth, Vint=3511 ± 750 m/s, and between 611 ± 5 and 655 ± 6 m depth, Vint=1839 ± 1620 m/s.
Event | Vrms (m/s) | Depth (m) | Range Vrms (m/s) | Range depth z (m) | Vint (m/s) | Range Vint (m/s) |
---|---|---|---|---|---|---|
R280 | 3,770 | 528 | 3,718–3,830 | 520–536 | 3,770 | 3,718–3,830 |
R327 | 3,737 | 611 | 3,707–3,767 | 606–616 | 3,511 | 2,762–4,075 |
R358 | 3,660 | 655 | 3,626–3,694 | 649–661 | 1,839 | 1,645–3,457 |
- Note. The interval velocities are derived for the layer above the reflection mentioned. For uncertainties see section 3.2.
3.3 AVA Analysis
To physically characterize the different media above and below the three different reflections, we plotted R against θ using equation 1. The AVA data consist of three shots with offset ranges from 3 to 300 m (shot 1), 303 to 600 m (shot 2), and 603 to 900 m (shot 3). To account for the shot to shot variability, we assumed a continuous transition in amplitude of reflection R280 at offset transitions from shot 1 to 2 and shot 2 to 3. This resulted in two scalars, 1.31 and 1.41, by which we multiplied the source amplitude A0 of shots 2 and 3. The direct path method described by Holland and Anandakrishnan (2009) to determine A0 was unsuitable as surface crevasses affected the attenuation of the direct wave too much. Offsets below 38 m were unsuitable due to source-induced noise, so the AVA data set covers an offset range from 38 to 900 m. The source-induced noise (linear moveout) partly overlaps the considered reflections, making the amplitude determination uncertain. We therefore focused the analysis on those parts without interfering noise which overly the reflections. The uncertainty of the reflection coefficient R(θ) mainly consists of two parts: uncertainty in the picked amplitude A1 of a reflection and uncertainty in the source amplitude A0. We approximated the uncertainty in A1 as the mean noise level over a 5 ms time window preceding each reflection. The uncertainty of A0 we approximated by using the multiple bounce method described by Holland and Anandakrishnan (2009) over several traces, resulting in a value of A0 = 1,874 ± 330 mV. With an attenuation α = 0.6 km−1 (explained in the discussion) we calculated the reflection coefficients of the three reflections identified for angle ranges of 3–40° (Figure 4b).
The first arrivals from the uppermost reflection, R280, can be tracked from an offset of 138 to 900 m (Figure 4a). The value of R is positive, generally increasing with increasing θ (Figure 4b). Its value begins at R = 0.01 at θ = 7∘, increasing steadily to R = 0.022 at θ = 40∘.
The amplitude of R327, which is positive and small, can be tracked reasonably to an offset of 360 m; thereafter it is discontinuous (Figure 4a). The value of R varies between 0.01 and 0.03 (Figure 4b). At offsets larger than 370 m (θ > 17∘), the first pick is unreliable. Between offset 488 m (θ = 22∘) and 600 m (θ = 26∘) the amplitude is negative but because of the discontinuity, we cannot unambiguously assign it to R327.
Reflection R358 can be tracked from an offset of 100 to 900 m (Figure 4a). The amplitude is positive and stronger then that of R280 and R327. At closer offsets the resolution is better but the reflection is discontinuous. At larger offsets (440 to 900 m) the reflection is continuous but with less resolution. The value of R generally increases with increasing θ. It varies between 0.1 (θ = 4∘) and 0.2 (θ = 28∘), after which it decreases to 0.1 at θ = 33∘ (Figure 4b).
4 Discussion
In July 2014 a thermistor string was installed at the onset of the seismic survey (i.e., CMP 870 of the along-profile) using hot-water drilling (Figure 3a). In all seven boreholes drilled in 2014 and 2016, connection to the subglacial hydrological system was confirmed by the rapid drainage of borehole water when the drill stem reached a depth of 605–611 m below the surface Doyle et al. (2018). R327 at 611 ± 5 m depth can thus accurately be interpreted to represent the ice-bed interface. Furthermore, we suggest that R280 at 528 ± 8 m depth originates from an englacial reflector and R358 at 655 ± 6 m depth is caused by the interface between the seismically stratified sequence and a hard base. From the temperature data (Figure 5) and a dominant frequency of 85 Hz we calculated the one way attenuation α = 0.6 km−1 for the entire ice column (Peters et al., 2012). To identify the nature of the four media separated by the three identified reflectors and in particular the nature of the subglacial conditions, we used three analyses as follows:
The first analysis comes from the polarity of the reflection coefficient R at normal incidence given by equation 2. This condition is satisfied for the shots with a fixed 22 m offset (i.e., 1∘<θ < 16∘), which includes the majority of both profiles. Using the same values for ρ, Vp, and lithology as Christianson et al. (2014), we calculated the acoustic impedance Z (Table 3) and R at normal incidence for the most likely media contrasts (Table 4). The seismic velocities of cold and temperate ice were adjusted to the conditions of the survey area. Depending on the porosity and water saturation, the P wave velocity of temperate ice can be as low as 3,470 m/s and up to 3,740 m/s (Kim et al., 2010).
Lithology | Vint range (m/s) | ρ range (kg/m3) | Z range (× 1,000, kg/(m2 s)) |
---|---|---|---|
Cold ice | 3,770–3,840 | 917 | 3,460–3,520 |
Temperate ice | 3,470–3,740 | 917–921 | 3,180–3,440 |
Lithified sediments/bedrock | 3,000–6,200 | 2,200–2,800 | 6,600–1,1740 |
Consolidated sediments | 2,000–2,600 | 1,600–1,900 | 3,200–4,940 |
Unconsolidated sediments | 1,700–1,900 | 1,600–1,800 | 2,720–3,420 |
Dilatant till | 1,600–1,800 | 1,600–1,800 | 2,560–3,240 |
Water | 1,450–1,500 | 1,000–1,020 | 1,450–1,600 |
Media contrast | R range |
---|---|
Cold ice-lithified sediments/bedrock | 0.304 to 0.667 |
Cold ice-consolidated sediments | −0.047 to 0.176 |
Temperate ice-cons sediments | −0.003 to 0.210 |
Temperate ice-unconsolidated sediments | −0.084 to 0.030 |
Temperate ice-dilatant till | −0.114 to 0.003 |
Temperate ice-water | −0.379 to −0.335 |
Consolidated sediments-lithified sediments/bedrock | 0.143 to 0.688 |
Unconsolidated sediments-lithified sediments/bedrock | −0.033 to 0.729 |
- A negative polarity indicates the presence of water; the larger the magnitude, the more water is present.
- A positive reflection coefficient indicates a drier bed; the larger the amplitude, the larger the impedance contrast to the underlying material (a harder, denser material) generally is.
- As the basal ice is temperate, a weak positive polarity may indicate unconsolidated sediments.
The shaded media contrast areas of R(θ) can partly overlap (Figure 4b). Distinguishing, for example, between dilatant till and unconsolidated sediments is not always possible. However, the polarity itself is a good indicator of whether water is present in the subglacial material as water tends to reduce the acoustic impedance.
The second analysis comes from the interval velocities, Vint, derived from the velocity analysis of the media between the three reflectors R280, R327, and R358 and the surface. As the velocity data are collected in the center of the survey area, we assume the derived velocities are representative for the whole survey area. Though the accuracy of the derived RMS velocities is only 0.5–1.5%, this accuracy causes large uncertainties in the interval velocities of the ice below the englacial reflection R280 and the stratified material. To identify the different media, we will use the most likely single interval velocity value.
The third analysis comes from the angle-dependent reflection coefficient R(θ) of the three reflectors, R280, R327, and R358.
4.1 Interpretation of the Four Media at the Interfaces of R280, R327, and R358
Migration of both the along-profile (Figure 3b) and across-profile (Figure 3e) was difficult as they suffer from smiles and a 3-D topography that is represented by 2-D profiles. We attribute the smiles to a strong velocity inversion at the ice-bed contact and to lateral variability in reflector amplitude. This amplitude variation is most likely caused by water-filled surface crevasses causing reflections of the direct wave throughout the shot records but also causing different attenuation depending on the travel paths of the seismic energy. Nevertheless, we are sufficiently confident in the results of our seismic data analysis to provide the following interpretation of the observed media properties and their stratigraphy.
Reflection R280 is an englacial reflector at 528 ± 8 m depth at the thermistor string location (CMP 870 of the along-profile). It is part of a series of reflections, 20 ms long-equivalent to ∼38 m of ice. The series is located at 528–566 m depth, well within the ice column and significantly above the confirmed ice-bed contact at 605–611 m depth. It is similar in appearance to the englacial reflection Horgan et al. (2008) identified at Jakobshavn Isbræ as the low-frequency arrival above which Holocene reflections appear, taking place in the lower 10–15% of the ice column. Reflection R280 appears at 14% in the lower ice column and may very well be the Holocene-Wisconsin transition which has been identified at this relative depth in this area (Karlsson et al., 2013).
R280 has a weak but positive polarity on, both the along- and across-profiles. Similar to previous seismic surveys undertaken in West Antarctica at Thwaites Glacier and Bindschadler Ice Stream (Horgan et al., 2011), the englacial reflection has bed conformity and long spatial wavelength variation in flow direction and short wavelength variation across-flow. We follow Horgan et al. (2011) in our reasoning that R280 is caused by a change in COF. Seismic P waves travel 5% faster parallel to the c axis of an ice crystal then perpendicular to it. When the ice crystals are randomly orientated, the bulk properties of ice are isotropic, but when the crystals have a preferred orientation, the bulk properties of ice become anisotropic and can, when the change in orientation is sudden, cause seismic reflections. Changes in Vp can be caused by a change in density, temperature, or crystal orientation. As R280 is within the ice column and up to ∼80 m above the bed, intrusion of basal debris is unlikely and the density of ice is constant. The temperature gradient is fairly constant here (Figure 5). We hence conclude that the most likely cause of these englacial reflections is an abrupt change in COF.
Stress regimes have been identified as causes of changes in COF, most often at ice domes or divides (Alley, 1988; Budd & Jacka, 1989; DiPrinzio et al., 2005; Diez et al., 2014; Hofstede et al., 2013; Montagnat et al., 2014) but more recently also at ice streams (Christianson et al., 2014; Horgan et al., 2008, 2011). As Alley (1988) and Horgan et al. (2011) summarize, the stress regime at ice streams causes c axes to rotate under vertical compression and bed parallel simple shear. This rotation leads to vertical clustering of c axes which in its turn hardens against vertical compression but softens simple shear (Budd & Jacka, 1989)
As we identified one englacial reflection we assumed the simplest scenario, namely, that the overlying ice of R280 is isotropic even though the stress regime at the survey area is complex where we can expect converging and stretching ice flow and consequently anisotropic overlying ice (Harland et al., 2013). The values of R(θ) fall within the green shaded area (Figure 4b), which represents the theoretical transition from isotropic ice to a Vertical Transverse Isotropic (VTI) structure with a cone opening angle of 0 (upper limit) to 45° (lower limit). Reflection R280 most likely marks the transition from isotropic to a (almost) VTI structure with a cone opening angle up to 45°. This anisotropic ice is vertically less compressible but horizontally twice more easily deformable, having an enhancement factor of ∼2 for simple shear (Cuffey & Paterson, 2010; Thorsteinsson, 2000). The value of the enhancement factor may be affected by the assumption of overlying isotropic ice.
The interval velocity of the top 528 ± 8 m of ice is 3,770 ± 60 m/s (Table 2). While this is slow for cold isotropic ice, the velocity is likely reduced by the presence of liquid water held within the ice matrix and crevasses. The interval velocity of the anisotropic ice below R280 is 3,511 ± 750 m/s (Table 2). We assume the entire ice column below R280 is anisotropic because there are no deeper reflections that show otherwise and because VTI structures found in ice cores in Greenland are present over longer depth ranges whereby the cone angle θ typically increases with increasing depth (Gow et al., 1991; Gusmeroli et al., 2012; Thorsteinsson et al., 1999).
We interpret R327 as the ice-bed contact at 611 ± 5 m depth at the thermistor string location. It is the top of a 45 m thick stratified sequence extending to R358 at 655 ± 6 m depth with an interval velocity of 1,839 ± 1,620 m/s. Considering the interval velocity of 1,839 ± 1,620 m/s and the weakness of R327 that occasionally disappears in the central part of the along-profile (22 m offset, 1∘<θ < 16∘), we interpret the subglacial material as unconsolidated sediments. This interpretation was supported in 2016, when the hot-water drilling team was able to penetrate, haltingly and over some hours, some tens of meters into this sequence (Doyle et al., 2018). The reflection coefficient R(θ) (Figure 4b) can be tracked from an angle of 4 to 16∘ where it has a positive but weak polarity. The till can be interpreted as an unconsolidated sediment having a positive reflection coefficient if overlain by temperate ice or if water is distributed widely in the pores of the sediment throughout the sequence. The disappearance of R327 at the start and end of the along-profile we attribute to a and thus a decreasing R(θ), a characteristic of a temperate ice-unconsolidated sediment interface.
Reflector R358 has a positive polarity throughout the along-profile. It is notably stronger than R327 and R280. The reflection coefficient R(θ) is positive throughout the angle interval from 0 to 40∘ (Figure 4b) with a value of R(θ) = 0.1 at 4° to R(θ) = 0.2 at 28°. The values fall well within the R(θ) interval of an unconsolidated-consolidated sediment interface (yellow shaded area) and are interpreted as such. This interpretation is confirmed by the increasing trend of R(θ) with increasing θ that is a characteristic of an unconsolidated-consolidated sediment interface. The reflection coefficient has a maximum around 28°, which seems unusual as the theoretically derived graph has a maximum at 40°, but this maximum is formed by the largest possible contrast of Vp, Vs, and ρ. It is more likely that the contrast of Vp, Vs, and ρ are less than the maximum contrast, as the stratified material between R327 and R358 is more consolidated with depth and probably have increasing values for Vp, Vs, and ρ with increasing depth.
4.2 Glaciological Implications of COF and Unconsolidated Basal Sediment
From the structure of the three events discussed in the results and the identification of the four media of the seismic profiles (Figure 3), we now discuss the glaciological implications.
In the along-profile we identified 80 m of anisotropic ice below R280 and ∼45 m of unconsolidated till below R327, both of which are more easily deformable than the upper 530 m of cold, stiff, isotropic ice and have important implications for ice flow. Doyle et al. (Doyle et al., 2018) reported that at CMP 870, 63–71% of the observed surface velocity of 592 m/a takes place as basal sliding or as deformation in the subglacial sediments and that the remaining 29–37% is explained by ice deformation which predominantly occurs in the lowermost 80 m of the ice column. Based on the current understanding of subglacial tills, we consider a Coulomb plastic rheology to be the most likely (Bougamont et al., 2014; Clarke et al., 2005), suggesting that the subglacial deformation will likely be concentrated at its top near the ice base and not distributed over the depth of the basal till layer. The observed increased consolidation with depth in the till layer is most likely an attribute of the till layer's own overburden pressure. While the effective pressure at the base is likely to be very small, a hydrostatic equilibrium would mean that effective pressure increases linearly with depth according to the difference between till density and the density of water contained in its pores
At the across-profile R280 forms an apparent syncline or fold. If R280 is the Holocene-Wisconsin transition as our data suggest, it would be an isochrone. The consequence is that at the deepest point of the syncline at CMP 500, that is, the older anisotropic ice, has disappeared. We hypothesize that the apparent syncline formed because ice flow in the drainage basin generally converges and that basal melting has caused the anisotropic ice to be lost. At the same time the unconsolidated till clearly terminates in the northerly direction at CMP 382 in the across-profile beyond which R358 becomes the ice-bed contact. This means that at the syncline's hinge point, reflection R358 is the ice-bed contact. We interpret its negative polarity to be caused by the presence of a large amount of subglacial water, which most likely is exclusively present at the ice-bed interface because ice at this location is in direct contact with the consolidated (R358) sediment observed below the till layer when the latter is present. We therefore conclude that ice must be sliding over a bed consisting of consolidated sediments at the syncline's hinge point at CMP 500.
Both profiles display different characteristics in bed stratigraphy. The along-profile (Figures 3a and 3b) shows less spatial variation and a more consistent top to bottom stratigraphy, whereas the across-profile (Figures 3c–3e) shows greater spatial variability in both the presence of anisotropic ice and the subglacial deposits. Considering the patchy character of the ice-bed contact in the across-profile, we can expect different types of ice and sediment deformation in different areas.
In order to quantify the deformation of subglacial till the along-profile would require a flow law for subglacial sediments, for example, a Coulomb-type plastic flow. For parts of the across-profile, where our analysis indicates the presence of consolidated sediments and subglacial water, a more traditional Weertman-type flow law would seem equally appropriate. The subglacial water content most likely varies over time and influences both a Coulomb type of till deformation and Weertman sliding, so preferably both flow laws should be able to take time-varying subglacial water pressures into account.
Ryser et al. (2014) observed and modeled the complex ice dynamics in along-flow direction caused by subglacial patches with varying basal slipperiness over time and space. Overlying colder and stiffer ice would enhance horizontal stress transfer between patches. They concluded that the ice dynamics in the ablation area was a result of an integrated response to the locally and time-varying ice-bed conditions. Our results reveal subglacial patches of different basal slipperiness of similar dimensions, overlain by colder stiffer ice. We infer that the distribution of subglacial water varies spatially with water partly present in the unconsolidated till layer and partly present in a basal water system at the ice-bed interface and almost certainly variable over time as the bed of Store Glacier accommodates a large amount of surface water during summer.
Our observations indicate that realistic modeling of ice dynamics in this region can be based on either a Coulomb-type plastic flow for till or a Weertman-type sliding law or equivalent. The advantage of the former is that basal traction can evolve from changes in the storage of water in the till layer (Bougamont et al., 2014). The advantage of the latter is that basal traction can evolve according to the configuration of a basal water system, which can be either be distributed or channelized. At the moment it is difficult to tell which model offers the best advantage, given that both till and basal water systems are likely to exert direct influence on ice flow.
5 Conclusions
In two profiles, parallel and transverse to the ice flow, we identified three seismic events separating four different media within and beneath Store Glacier. From the derived interval velocities and the reflection coefficients we interpreted the four different media to be (1) an upper ∼530 m thick layer of isotropic ice; (2) an ∼80 m thick layer of anisotropic ice, most likely having a VTI structure; (3) an ∼45 m thick layer of unconsolidated and acoustically stratified till; and (4) a harder base consisting of consolidated sediments.
These three seismic events could be tracked throughout both profiles but with changing stratigraphy and structure. The along-profile contains subhorizontal reflectors with little topography and little spatial variation, whereas the across-profile has considerable topography and spatial variation. The across-profile contains dipping englacial reflections and an absence of the oldest anisotropic ice at the hinge of the syncline-like structural fold. We hypothesize that the syncline formed in response to converging ice flow and that the oldest ice at the bottom of the hinge lines axial plane was lost due to basal melting. We also found a phase shift from positive to negative polarity which we interpret as a change from water stored preferential in the pore spaces of a relatively thick subglacial till layer to water contained largely at the ice-bed interface where till is absent and ice is underlain by a consolidated and more compact sediment. These observations suggest that we can expect two different types of ice and sediment deformation within less than a kilometer of each other: a Coulomb type of plastic flow where the unconsolidated till below the ice is present and a Weertman type of sliding where consolidated sediments and subglacial water are present. We do not know whether free water at the basal interface requires till to be absent as found here, or whether the latter is a coincidence. We conclude by stating that these type of bed properties and their spatial variations seem to be common in Western Greenland (e.g., Ryser et al., 2014). But direct observations from the bed are of advantage to decide for the optimal basal parameterization in numerical ice flow models and whether those should include till as well as basal water systems.
Our observations imply that realistic modeling of ice dynamics in this region require a combination of both a Coulomb-type plastic flow for till and a Weertman-type sliding law or equivalent. How such a hybrid parameterization could be implemented under transient subglacial drainage and ice flow dynamics at typical higher-order ice sheet model grid resolutions (1–10 km) remains a major outstanding challenge for accurate forecasting of Greenland's fast-flowing outlet glaciers.
Acknowledgments
This research was funded by the UK National Environment Research Council (NERC) grants NE/K006126/1 and NE/K005871/1. We kindly thank Johannes Bondzio, Thomas Kleiner, and Pascal Bohleber for the preparations of this survey. We kindly thank Ann Andreasen and the Children's Home in Uummannaq for their generous hospitality and providing us with an excellent roof over our heads in Uummannaq. We also thank Carlos Martín for advice concerning the enhancement factor of the anisotropic ice and Emma Smith who tirelessly helped to improve the manuscript. We want to thank the three reviewers for their excellent suggestions and remarks helping to improve this manuscript. Alun Hubbard gratefully acknowledges support from the BBC's Operation Iceberg for the deployment of the GPS reference station and a Professorial Fellowship from the Centre for Arctic Gas Hydrate, Environment and Climate, funded by the Research Council of Norway through its Centres of Excellence (grant 223259). We thank the tireless crew and skipper of S/V Gambo for logistical support. The data sets presented in this paper will be made available prior to publication at https://doi.org/10.1594/PANGAEA.884529.