2. PETERMANN GLACIER STUDY AREA

Petermann Glacier is a large marine terminating ice stream located on the north-west coast of the Greenland ice sheet at 81°N and 62°W (Fig. 2). It drains ~4% of the total ice-sheet area (Munchow and others, Reference Nick2014) and is one of only seven ice streams in Greenland with a permanently floating section (Moon and others, Reference Moon, Joughin, Smith and Howat2012). Inland, Petermann Glacier is grounded on bedrock more than 300 m below present day sea level and its 1280 km² floating ice tongue flows through a steep sided, 20 km wide fjord into the Hall Basin in the Nares Strait. Satellite observations of surface elevation change inland of the Petermann Glacier grounding line show a moderate rate of thinning (0.3 m a⁻¹) for the period 2003–07, of which 50% is directly attributed to a negative surface mass-balance anomaly (Pritchard and others, Reference Pritchard, Arthern, Vaughan and Edwards2009). Episodic calving events in 1992, 2010 and 2012 have decreased the area of the floating ice shelf by ~40% (Nick and others, Reference Nick2012; Munchow and others, Reference Munchow, Padman and Fricker2014). However, there is no evidence to suggest that these calving events are occurring with greater frequency, or that they have affected the glacier speed, which has remained steady at ~1 km a⁻¹ in the fastest regions (Nick and others, Reference Nick2012). This is in part because, at Petermann Glacier, high rates of channelised basal melting remove the vast majority (80%) of floating ice before calving can occur, making ice/ocean interactions the dominant control on ice mass imbalance (Rignot and Steffen, Reference Rignot and Steffen2008). Although ship-based studies confirm that there is sufficient heat available within the fjord waters to drive the rapid rates of basal melting inferred from satellite observations (Johnson and others, Reference Johnson, Münchow, Falkner and Melling2011) it is not certain whether potential changes in ocean temperature, mixing, or sea ice cover might lead to additional melting potential, fuelling speculation that a warming ocean could trigger future grounding line retreat on Petermann Glacier (Johnson and others, Reference Johnson, Münchow, Falkner and Melling2011; Nick and others, Reference Nick2013).

Fig. 2. Map of Petermann Glacier, a marine terminating ice stream in north-west Greenland. The ice stream is shown by an ERS-1 synthetic aperture radar image, and flows from the bottom to top of the image. The 1995/96 grounding line is shown in red, along-flow transects are marked in white (A–G), the calving front is shown in cyan, and ICEBridge flight-line 1 (west) and 2 (east) separated by 2.9 km is shown in blue. Also shown are the seed locations chosen for interferometric phase unwrapping (yellow), and for tide model heights (green). The inset shows the location of Petermann Glacier in Greenland and the location of the start and end points of the fjord (red) and Nares Strait (blue (north) and green (south)) tide model transects.

3. DATA AND METHODS

Maintaining interferometric phase coherence in repeat pass SAR acquisitions is challenging over ice-covered terrain, because the surface rapidly deforms due to flow and in response to changing meteorological events such as snow deposition and redistribution and melting. The nominal 35 d orbit repeat period of the European Space Agency's (ESA) ERS 1 and 2 satellites is typically too long to acquire viable (i.e. coherent) repeat-pass interferometric data over ice, so both platforms were moved into shorter repeat orbits during campaigns dedicated to this purpose. Between 28 December 1991 and 30 March 1992, ERS-1 was placed in a 3 d orbit repeat cycle (termed the first ice phase) and, after the success of this campaign, it was repeated in 1993/94 and in 2011 with ERS-2 in order to acquire repeat measurements over Greenland and Antarctica. SAR data acquired by ERS-1 and 2 between 21 March 1995 and 05 June 1996, when both satellites orbited in tandem 35 d repeats, separated by 1 d, is also suitable for interferometry over ice-covered regions as the short temporal baseline allows phase coherence to be maintained between SAR images acquired from both sensors. Here, we used ERS-1 and 2 data acquired on track 12, frame 1953 over Petermann Glacier during all 3 d ice campaigns and the 1 d tandem campaign, between 1992 and 2011 (Table 1), to produce measurements of the grounding line.

Table 1. Details of all SAR data used in this study, including sensor, track number, acquisition dates and temporal baseline

The data are listed in rows identifying each SAR frame element of the 17 quadruple difference interferograms used to detect the grounding line (identifiable as 92a through 11d).

We processed ERS-1 and ERS-2 data from raw to Single Look Complex (SLC) images using precise Department of Earth Observation and Space Systems (DEOS) orbit ephemerides (Scharroo and Visser, Reference Scharroo and Visser1998) when available. Temporally sequential SLC master and slave image pairs were formed from ERS-1 and 2 data acquired prior to 1997 (Table 1). However, failure of the ERS-2 gyroscope in 2001 (Rosich and others, Reference Rosich, Meadows, Schättler, Grion and Emiliani2001) resulted in larger and less stable Doppler centroid frequencies, and so it is not always possible to pair temporally sequential images in data acquired during the latter period. To achieve high-interferometric coherence low Doppler centroid differences are required to ensure sufficient spectral overlap, therefore in 2011 SLC image pairs were formed when the Doppler centroid difference was <800 Hz and when temporal baselines were <9 d. Each SAR image pair was co-registered using common features in the backscatter intensity images, with the aid of initial co-registration offsets determined from the orbital state vectors. Assuming the influence of atmospheric delay on the phase signal is negligible, the interferograms computed from each SAR image pair contain signal contributions from the Earth's curvature, topography and surface displacement, as well as noise. We simulated the Earth curvature and topographic phase signals using the orbital geometry of each SAR image pair and using a DEM generated from the ASTER GDEM data, and we assume that no significant ice-surface elevation change has occurred in the time interval between the DEM and SAR data acquisition. These signals were then subtracted from the smoothed interferograms to reduce noise and then isolate the surface displacement phase signal. At the Petermann Glacier, displacement is caused by ice flow and, in floating sections, by ocean tides.

We then combine terrain-corrected interferograms to form quadruple difference interferograms (Rignot, Reference Rignot1998a), a process that removes common signals due to constant ice flow. Over short-time periods, this approach is usually effective because ice flow is relatively stable in comparison with tidal motion; however, short-term changes in ice velocity such as the tidally induced motion observed on Rutford Ice Stream (Rosier and others, Reference Rosier, Gudmundsson and Green2015), would not be removed using this technique. The remaining phase signal, which is manifest as a dense band of interference fringes at the boundary between grounded and floating ice (Fig. 3a), can then be attributed to vertical surface displacement caused by ocean tides. We unwrapped the quadruple difference interferogram phase across the glacier grounding zone using the branch cut method (Goldstein and others, Reference Goldstein, Zebker and Werner1988) to calculate the absolute differential displacement in the satellite line of sight (Fig. 3b). It was not possible to initiate phase unwrapping in the same location in all instances (Fig. 2) due to temporal decorrelation of the SAR imagery inland of the glacier grounding zone. This decorrelation also limited the extent of interferometric data, necessitating the use of manual bridges to link areas of disconnected phase in some places. The bridge locations were selected by identifying the successfully unwrapped regions in each interferogram, and then visually pairing neighbouring unwrapped and wrapped pixels in the same interferometric fringe. The unwrapped phase value was assigned from the reference to the wrapped pixel, and then the unwrapping procedure was recomputed. Finally we calculated differential vertical displacement from the unwrapped phase using the satellite geometry (Fig. 3c).

Fig. 3. Wrapped (a) and unwrapped (b) quadruple difference interferometric fringe pattern across the grounding zone of Petermann Glacier, from QDInSAR pair 95a. The grounded (green) and floating (blue) sections of the transect are identified above a profile of the differential vertical displacement (black) extracted along a transect F (white dashed) (c).

We identified the Petermann Glacier grounding line by manually delineating the inland limit of tidal flexure, following the method of Rignot and others (Reference Rignot, Mouginot, Morlighem, Seroussl and Scheuchl2014). In longitudinal profiles (Fig. 3c) grounded ice shows no significant vertical displacement, in contrast to the floating ice shelf, which shows a relative displacement ranging from −124 to +143 cm at times of extreme tidal difference (Fig. 4). In all 17 quadruple difference interferograms the grounding zone is identifiable as a ramp between 7 and 47 interference fringe cycles across the full width of the ice stream, oriented perpendicular to the direction of flow. There is a strong (R ² = 0.94) positive correlation between the fringe density and the magnitude of the ice-shelf vertical displacement. The inland limit of tidal flexure is more difficult to identify in differential interferograms with a lower fringe density because the magnitude of the vertical displacement signal is smaller; however, the fringes that are present are spread over approximately the same grounding zone width. To investigate the influence of fringe density on the position of the grounding line, we scaled the wrapped phase signal in each differential interferogram by factors of two, three and four. Although this process increased the density of fringes in the grounding zone, it also scaled the phase noise, and when higher scaling factors were employed the phase signal in the differential interferogram became saturated, rendering the grounding zone undetectable. We mapped the grounding line position in the original and phase scaled differential interferograms and examined the difference in position of the inland limit of tidal flexure. Although the fringe density was much higher in the phase scaled images, there was no visible change in the grounding line location measured, and so we used the unscaled differential interferograms to identify the grounding line position throughout the rest of this study.

Fig. 4. Relative vertical displacement along the transect E flow-line profile of the Petermann Glacier grounding zone, measured using 17 quadruple difference interferometry (Table 1). Also shown (coloured dots) are relative tidal amplitudes at the same epoch as determined from the AODTM-5 model Arctic Ocean tide model. Between 0 and 8 km, there is no significant vertical displacement, indicating that this section of the glacier is grounded on bedrock. However, from 8 km and farther seaward, up to 1.5 m of relative displacement are recorded, indicating this section of the glacier is influenced by the ocean tide and therefore floating.

We estimated the uncertainty of each QDInSAR grounding line measurement by translating noise in the vertical deformation profiles into a lateral error in the grounding line position. A running mean of the vertical deformation was measured from all 17 quadruple difference interferogram profiles extracted along transect D (Fig. 2), with the residuals computed as the difference of each point from the local mean. All 17 profiles exhibited low variability with a mean absolute difference of 0.4 ± 0.2 cm, and a larger total range of 6.5 cm. The range of the residuals measured along each profile is comparable on both grounded and floating ice, indicating that the uncertainty is independent of tide amplitude. This suggests that the uncertainty is systematic rather than geophysical in origin, and that it may reasonably be used as a formal error budget associated with QDInSAR grounding line measurements made in other areas. We retrieved the standard deviation of the residuals from the mean at the grounding line of each displacement profile, and then translated this into the lateral error in grounding line position by measuring the distance seaward of the grounding line over which the mean vertical displacement was within the range of error. The mean lateral precision of a QDInSAR grounding line position is 30 m with a total range up to 100 m.

5. ANALYSIS OF FACTORS AFFECTING GROUNDING LINE MIGRATION

Although a modest secular retreat of the Petermann Glacier grounding line cannot be ruled out, the high variability suggests that other factors are responsible for the majority of its motion. The position of an ice-sheet grounding line is influenced by changes in the ice thickness, in atmospheric pressure, and in ocean tides, and the pattern of any retreat is in turn governed by the bedrock and ice geometry (Thomas, Reference Thomas1984). However, the influence of these factors will vary in space and time. Progressive grounding line retreat has been observed over annual to decadal timescales at the Antarctic Peninsula following ice-shelf collapse (Rack and Rott, Reference Rack and Rott2004), and in West Antarctica through sustained ocean-driven melting (Park and others, Reference Park2013). Fluctuations in ocean tides and atmospheric pressure will cause grounding line positions to move over much shorter timescales. For example, at the Filchner-Ronne Ice Shelf, ocean tides are estimated to cause over 130 m change in grounding line position between high and low tide (Smith, Reference Smith1991). In areas where grounding line migration has been recorded, irregular patterns of movement have occurred. For example, although the Pine Island Glacier grounding line retreated by over 28.4 km between 1992 and 2011, the retreat has been asymmetric and episodic in time due to the presence of a prominent, subglacial bedrock pinning point (Park and others, Reference Park2013). Likewise, although the Totten Glacier grounding line retreated by 1–3 km along the south and north lobes between 1996 and 2013, advance was observed in the central trunk of the ice stream over the same time period (Li and others, Reference Li, Rignot, Morlighem, Mouginot and Scheuchl2015).

Because the Petermann Glacier grounding line has migrated forwards and backwards on numerous occasions during our survey period (Fig. 7), it seems likely that a short-term forcing mechanism is responsible. Ignoring the effects of atmospheric pressure changes, which are very small, the main controlling factors on grounding line position are ocean tides and localised changes in ice thickness. We use a simple geometrical relationship (Rignot, Reference Rignot1998b) to simulate these effects on the position of the Petermann Glacier grounding line. In this formulation Eqn (2) grounding line positions $(\dot x)$ migrate back and forth with time by following changes in ocean tide $(\dot z)$ and ice thickness $(\dot h)$ , where $(\dot h)$  > 0 for thickening, $(\dot x)$  > 0 for hinge-line retreat, alpha and beta are the surface and basal slopes respectively, counted positive upward, and ρ _w and ρ _i are the densities of sea water (1027.5 kg m⁻³) and ice (900 kg m⁻³), respectively. Migration rates are asymmetrical, with larger migration upstream than downstream (Li and others, Reference Li, Rignot, Morlighem, Mouginot and Scheuchl2015; Tsai and Gudmundsson, Reference Tsai and Gudmundsson2015) and further details can be found in Tsai and Gudmundsson (Reference Tsai and Gudmundsson2015). Using this relationship, changes in grounding line position associated with changes in tide and ice thickness can be simulated.

(2) $$\dot h - \left( {\displaystyle{{\rho _{\rm w}} \over {\rho _{\rm i}}}} \right)\dot z = \left\{ {\matrix{ {\left[ {\alpha - \beta \left( {1 - \; \displaystyle{{\rho _{\rm w}} \over {\rho _{\rm i}}}\; } \right)} \right]\dot x,\; \;{\rm if}\; \; \dot x\; \lt \; 0,} \cr {\left[ {\left( {\displaystyle{{\rho _{\rm i}} \over {\rho _{\rm w} - \; \rho _{\rm i}}}} \right)\alpha - \beta } \right]\dot x,\; \;{\rm if}\; \; \dot x\; \gt \; 0.} \cr } } \right.\;$$

To estimate the surface and bedrock slopes, and the potential size of short-term fluctuations in glacier thickness, we used geometry data acquired along two stream-wise profiles of the Petermann Glacier in 2010 by the NASA Operation Ice Bridge Airborne Topographic Mapper (ATM) lidar and Multichannel Coherent Radar Depth Sounder (MCoRDS) (Allen, Reference Allen2013) (Fig. 10). Although the ice-surface elevation is similar along both flight lines, there are large differences in the elevation of the ice base (Fig. 10). Along the western flight-line, there is an abrupt 420 m change in the elevation of the glacier base over a 2.6 km distance, in sharp contrast to the eastern flight-line where the step is only 75 m over a similar distance (Fig. 10a, b). The MCoRDS instrument detects the ice/bedrock interface on the grounded portion of the ice stream and the ice/ocean interface on the ice shelf, assuming re-frozen marine ice is not present, therefore the ice base only represents the bedrock topography inland of the grounding line. We calculated ice surface and bedrock slopes along a 4.4 km section (the mean width of the flexure zone) of each flight-line centred on the most inland grounding line position measured from the interferometric data (Fig. 10). Using these data, the estimated ice surface (α) and bedrock (β) slopes from the western flight-line are 0.83 and −0.11% respectively, and from the eastern flight-line they are 0.94 and 0.42%, respectively.

Fig. 10. Ice surface (blue curve) and ice bottom (grey curve) elevation measured along adjacent western (a) and eastern (c) stream-wise profiles of the Petermann Glacier (Fig. 2). The spread of grounding line positions measured in this study are highlighted (grey shaded area). We also show regions over which the surface and bedrock slopes are computed (thick black curve), and a polynomial fit (red dashed curve) to the ice-surface elevation from which ice thickness anomalies (b) and (d) in the vicinity of the grounding zone are calculated.

Given that such a strong relationship exists between ice-shelf vertical displacement and ocean tides at Petermann Glacier (Fig. 6), we conclude that the floating tongue is in hydrostatic equilibrium with the surrounding ocean, meaning that the grounding line position ought to be sensitive to short-term changes in the ocean tides. We simulated the degree of tidally induced grounding line migration by scaling estimates of the differential tide $(\dot z)$ derived from the AODTM-5 Arctic tide model (Table 2) by the tidal migration factors for each flight line. Based on the maximum simulated differential tide (4.4 m), we estimate that the Petermann Glacier experiences up to 560 m of tidally-induced grounding line motion. For comparison, this range of tidally-induced grounding line motion is approximately three times smaller than at the Pine Island Glacier in West Antarctica (Rignot, Reference Rignot1998b), where the bedrock slope, in particular, is more pronounced. The average simulated tidally-induced relative grounding line motion of the Petermann Glacier at the epochs of our QDInSAR survey was 45 and 38 m along the western and eastern flight-lines, respectively. By comparison, the mean actual grounding line variability measured along transects D and E adjacent to each flight-line (Fig. 2) was 193 and 281 m, respectively. We conclude, therefore, that ocean tides are responsible for only a small fraction (18% on average) of the observed grounding line movement.

Because the Petermann Glacier grounding line movement has been irregular in space (Fig. 7), it is possible that it has arisen through temporal changes in ice thickness. Such changes can be due to localised variations in the thickness of ice that is advected downstream, or temporal variations in the rate of basal melting. In the absence of detailed information on rates of basal ice melting, we examined the evidence for changes in inland ice thickness over time. Although there is some evidence for modest long-term change in dynamic ice thickness (0.15 m a⁻¹) on Petermann Glacier (Pritchard and others, Reference Pritchard, Arthern, Vaughan and Edwards2009), given the geometrical configuration, these changes would not induce substantial grounding line motion. However, previous studies (Rignot and Steffen, Reference Rignot and Steffen2008) have shown that there are large (±25 m) stream-wise fluctuations in the thickness of the floating section (Fig. 10), which could potentially influence the location of the grounding line if they are advected downstream. To assess their potential impact, we characterised the ice thickness variations on Petermann Glacier by computing the ice thickness anomaly from the difference between the mean polynomial fit to the ice-surface elevation profiles within a 40 km region centred on the 2011 grounding line (Fig. 10). The mean absolute variability was 7.1 and 8.1 m along the western and eastern flight-lines respectively, with a combined range of 61.7 m. Ice thickness changes of this magnitude would lead to 490 m of grounding line motion – 2 to 3 times the observed variability – if they were to affect the glaciers hydrostatic balance.

Tidally-induced motion is too small to account for the range of grounding line migration observed on Petermann Glacier (Fig. 8). Moreover, when applied as a correction to the grounding line position, the simulated tidal motion does not reduce the variance in the observed grounding line position, suggesting that ocean tides are not the dominant cause of grounding line variability on Petermann Glacier. While localised ice thickness change many not fully translate into change in grounding line position due to the effect of lateral support from surrounding ice, the motion attributed to the range of ice thickness anomalies is greater than the observed mean grounding line variability and therefore may be sufficiently large to account for all the observed motion. Other factors, such as a change, or spatial variability in the basal boundary conditions, may have also modulated the grounding line position; however, new observations or a dedicated modelling study would be required to investigate this further. It is unclear what process has driven the relatively large shifts in grounding line position that have occurred at the glaciers north-east shear margin. Alternative causal mechanisms, such as adverse snow loading on the floating section or atmospheric pressure variations, are unlikely to exhibit spatial variability over scales small enough to induce such changes. In consequence, short-term changes in ice thickness remain the most likely cause of the observed grounding line motion.