Introduction
At the end of the 20th century, the mass loss of glaciers and ice caps (excluding those of Antarctica and Greenland) is estimated to have formed the largest cryospheric component of the observed sea-level rise of 3.1 ± 0.7 mm a−1 (Reference Lemke and SolomonLemke and others, 2007). Estimates of the 21st-century sea-level contribution due to glaciers and ice caps vary by a factor of two (Reference Van de Wal and WildVan de Wal and Wild, 2001; Reference Raper and BraithwaiteRaper and Braithwaite, 2006; Reference Meehl and SolomonMeehl and others 2007) depending on how the sensitivity of ice mass balance to future climate forcing is modelled. Because ice velocity is a factor in the estimation of glacier mass balance, knowledge of its seasonal and interannual variability is important to gain an improved understanding of the response of glaciers and ice caps to expected climate change.
About 11% (11 200 km2) of Iceland is covered by temperate ice (Fig. 1), comprising roughly 4% of the 272 200 km2 of Arctic land ice outside of Greenland (Reference DowdeswellDowdeswell and others, 1997). In the maritime Icelandic climate, snow accumulation is sensitive to winter temperature and the position of the paths of the North Atlantic low-pressure weather fronts. As a consequence, the temperate glaciers of Iceland are dynamically active and respond sensitively to climatic fluctuations (Reference BjörnssonBjörnsson, 1979). On the highest parts of the main ice caps, average annual temperatures are below freezing. Due to a steeply decreasing precipitation gradient from south to north, south-flowing glaciers tend to be steep and fast-flowing, terminating at low altitude in areas of high ablation. Conversely, north-flowing glaciers have lower accumulation in their higher reaches, shallower slopes and terminate in broad fronts at higher altitudes. During the early 20th century, there was a general recession of Icelandic glaciers which accelerated after the 1930s and slowed after the 1960s (Reference BjörnssonBjörnsson, 1979).
Fig. 1. Location of Langjökull and other major ice caps in Iceland.
With an area of 925 km2, Langjökull is Iceland’s second largest ice cap (Reference Björnsson and PálssonBjörnsson and Pálsson, 2008). Radio-echo sounding has revealed a mean ice thickness of about 200 m and a maximum of 580 m (Reference Björnsson, Gudmundsson, Jóhannesson, Pálsson, Aðalgeirsdóttir and HaraldssonBjörnsson and others, 2006). Total ice volume is estimated to be 195 km3, which is equivalent to 0.5 mm of eustatic sea-level rise (SLR). The southern outlet glacier of Hagafellsjökull Vestri flows down to an altitude of 500 m and, following at least 40 years of quiescence, has experienced four separate periods of glacier surging between 1971 and 2002 affecting an area of 150 km2 (Reference Björnsson, Pálsson, Sigurðsson and FlowersBjörnsson and others, 2003). The surface mass balance of Langjökull ice cap (LIC) has been measured at 22 stake locations since 1996. The net surface mass balance was negative from 1996 to 2001, resulting in a loss of 5.36 km3 of ice or 3% of the total ice-cap mass. Although there is no simple relationship to explain the observed mass loss, the minimum winter surface mass balance in 2001 coincided with a precipitation minimum recorded at a nearby meteorological station (Hveravellir), and, in consequence, it would appear to have meteorological origins (Reference Björnsson, Pálsson and HaraldssonBjörnsson and others, 2002).
In this study, we use interferometric synthetic aperture radar (InSAR) to determine the velocity of LIC in 1994, and ground-based global positioning system (GPS) observations made in 2001 to investigate the extent to which velocity fluctuations may be responsible for recent mass trends.
Methods
A repeat-pass interferogram calculated from synthetic aperture radar (SAR) data records surface motion within the data repeat interval (Reference Goldstein, Engelhardt, Kamb and FrolichGoldstein and others, 1993). If the perpendicular component of distance between sensor positions of the repeat-pass data is non-zero, there is an additional topographic contribution to the interferometric phase which can be removed to isolate the motion contribution (Reference Kwok and FahnestockKwok and Fahnestock, 1996). A single interferogram measures only the component of motion in the satellite line of sight (LOS), orthogonal to the flight path. To estimate surface motion in three dimensions, interferograms from ascending and descending satellite orbits can be combined with the additional assumption of ice motion parallel to the ice surface (Reference Joughin, Kwok and FahnestockJoughin and others, 1998). In general, ice does not flow parallel to the surface; instead, ice flow is inclined slightly upwards in the ablation zone and slightly downwards in the accumulation zone (Reference PatersonPaterson, 1994). For LIC, where slopes are low and both accumulation and ablation are modest, the assumption of surface-parallel flow should not yield significant errors in estimates of vertical motion. Estimates of horizontal components of motion should be relatively unaffected by deviations from surface-parallel flow because the SAR look direction is close to nadir (∼24°) and because surface gradients of LIC are low. In the absence of SAR data acquired from separate orbits, the ice-flow direction can be estimated from the direction of maximum averaged (over an area with a radius of 10–20 times the ice thickness) downhill slope (Reference PatersonPaterson, 1994).
Repeat-pass interferograms were derived from pairs of European Remote-sensing Satellite-1 (ERS-1) SAR images obtained from satellite passes sequentially 3 days apart in late February 1994 (Table 1). Data were acquired from both ascending and descending satellite orbits, providing InSAR data oriented in approximately orthogonal directions. The SAR scenes were co-registered to sub-pixel accuracy using a cross-correlation of the detected single-look complex data (Reference Wegmüller, Werner, Strozzi and SteinWegmüller and others, 1998). We removed the ‘flat-Earth’ component arising from the Earth’s curvature using precise orbit information (Reference Scharroo and VisserScharroo and Visser, 1998). The phase contribution due to topography was removed by subtracting a synthetic interferogram (Reference Massonnet and RabauteMassonnet and Rabaute, 1993) generated from a digital elevation model (DEM) of LIC. This external DEM was constructed from a GPS survey conducted in April 1997, with values in the horizontal axes equally spaced every 200 m and an estimated vertical accuracy of 2–5 m. After accounting for these topographic signals, the phase due to motion during the repeat-pass interval was unwrapped (Reference Wegmüller, Werner, Strozzi and SteinWegmüller and others, 1998) and from this we generated ice displacement maps in both ascending and descending geometries.
Table 1. ERS SAR data used in our study
LIC displacement maps formed from InSAR data acquired in ascending and descending satellite orbits were then combined with the surface DEM to derive a three-dimensional (3-D) surface-parallel ice velocity vector field for about 50% of the ice cap (Fig. 2). Ice velocity errors in areas with dual-look InSAR coverage were about 5 m a−1 as estimated from the range of ice velocity values measured for stationary bedrock (root-mean-square (rms) value is 4.5 m a−1). However, to improve spatial coverage we augmented the 3-D velocity field with estimates of ice motion derived from single-look InSAR displacement fields in other areas, excluding data for which the angle between sensor look direction and local aspect was >72°. This procedure introduced an additional error due to uncertainties in the ice-flow direction, which we estimate to be ±5°. As the southern part of LIC was not covered by ascending-pass data, ice velocities were calculated in that location using descending-pass data only and we estimate errors for this area to be ∼10 m a−1 as estimated in the same way as the dual-look error (rms value is 8.8 m a−1).The sensor LOS for ascending passes is almost perpendicular to the direction of ice flow, and is therefore insensitive to ice motion at the south-flowing glaciers in the southern part of the ice cap.
Fig. 2. Ice velocity map with 100 m elevation contours, GPS stake locations and data transects shown in Figures 3 and 4, projected over SAR intensity image. Locations of data transects are shown in white: northwest transect (NW), northeast transect (NE), Leidarjökull (L), Kirkjujökull (K), Nordurjökull (N), Sudurjökull (S), southwest transect (SW), Thristapajökull (T). Areas of 3-D velocity (green), ascending pass only (yellow) and descending pass only (blue) are shown in the inset. Radar look direction (RLD) for ascending (Asc) and descending passes (Desc) is also shown.
Finally, ice motion was determined at 22 stakes positioned across LIC (Fig. 2) during the summer of 2001 (April to October) over a period of 170 days using differential GPS. The error on the stake velocities was calculated by dividing the sum of the error in the position of the differential GPS measurements (2 × 50 cm) by the interval between measurements (170 days) to obtain a value of ±2.2 m a−1.
Results and Discussion
Our InSAR data represent the first detailed map of the LIC velocity field (Fig. 2). Eight outlet glaciers are apparent from the InSAR velocity data, with the majority located in the northern half of LIC. Three glaciers flow to the west or northwest and the remainder flow to the east or southeast. Although apparent from GPS measurements (locations 1–8, Fig. 2), the southward-flowing outlet glacier of Hagafellsjökull Vestri is not obvious in the InSAR data due to the large angle between the ice-flow direction and the radar look direction, a condition that is not favourable for detecting ice motion from single-pass data. These eight glaciers surveyed range in area from 18 to 71 km2 (Table 2), and the maximum ice speed we have recorded is 75 m a−1 at the terminus of Sudurjökull in the southeast part of LIC. Derived velocities are below the InSAR measurement error for 32% of LIC and are omitted from Figure 2. The elevation at which the surveyed glaciers reach their maximum velocity varies between 1200 m for the northeast glacier to 870 m for Kirkjujökull, with an average across all eight outlet glaciers of 1000 m.
Table 2. InSAR velocity transect attributes. Position and elevation of maximum speed are the distance from the margin (km) and altitude (m), respectively, at which maximum ice speed occurs
We extracted InSAR velocity data along eight transects (see Fig. 2) of LIC that passed close to the centre of each principal glacier and were linked by the GPS survey sites, to allow for a more detailed comparison of the two datasets. A summary of LIC geometry and flow along each transect is shown in Table 2. The glaciers can be grouped by the shape of their InSAR velocity profiles as shown in Figure 3. Along the northwest and northeast profiles, ice velocity increases progressively from near-zero at the highest elevations to a maximum about 2.5 km from the ice margin at an elevation of about 1150 m, and decreases gradually thereafter to about zero at the terminus. The southwest transect has similar characteristics, although, due to loss of coherence near the ice margin, InSAR velocity was not retrievable for the whole profile. Although Kirkjujökull exhibits a similar profile, ice velocity at the terminus is about 20 m a−1.At Thristapajökull, the ice velocity increases along the transect until it reaches its maximum value of 75 m a−1 about 3 km from the margin. Below this, ice velocity decreases with a roughly constant rate to about 30 m a−1 at the ice margin.
Fig. 3. InSAR-derived velocity for winter 1994 (solid curve) and 1997 ice surface (dashed curve) for transects shown in Figure 2. Solid points with error bars show 2001 summer velocity from stake measurements. Grey areas show error for InSAR velocity values.
The three remaining transects exhibit markedly different behaviour from those above as well as each other (Fig. 3). Ice velocity for Leidarjökull increases rapidly from the ice divide to a maximum of 40 m a−1 within a short distance (4 km) of the ice divide. Thereafter, it remains approximately constant at about 30 m a−1 before decreasing to about 10 m a−1 in the final 2 km. The lower part of the outlet covers a caldera where ice thickness is ∼400 m. The central part of the surface profile has a shallower surface gradient, and a rough estimate of the deformation velocity (from surface slope and ice thickness) yields ∼15 m a−1, which accounts for only half of the observed surface flow. Calculations of basal water pressure based on radio-echo sounding studies of bedrock topography (Reference Flowers, Björnsson, Geirsdóttir, Miller and ClarkeFlowers and others, 2007; Reference Guðmundsson, Björnsson, Aðalgeirsdóttir, Jóhannesson, Pálsson and SigurðssonGuðmundsson and others, 2009) suggest that sliding at the bed is enhanced for Leidarjökull, which helps to explain the concave-up surface profile. At Nordurjökull, ice velocity increases at roughly a constant rate along the length of the profile, although, due to coherence loss near the terminus, we were unable to retrieve InSAR velocity for the final 1 km. The lower slopes of this glacier are narrow and steep and the outlet flows into the Hvítárvatn lake. Though the terminus does not float, ice breaks off at the margin into the lake, and the presence of water is likely to reduce basal friction, which may explain the high ice velocity near the terminus. Along Sudurjökull, ice velocity increases gradually downslope from the ice divide to about 60 m a−1 where it remains roughly constant for ∼2 km. At 3 km from the margin, ice velocity drops by 20 m a−1 in 500 m horizontal distance; although low coherence prevented retrieval of the final 1 km, it is likely that ice velocity at the terminus is about 40 m a−1. This area of high velocity on the lower slopes suggests that in February 1994 Sudurjökull was experiencing a surge. The record of GPS-surveyed velocities at site L13 between summer 1997 and summer 2008 also suggests that another surge started in summer 1999 (the velocity in summer 1999 is 65 m a−1) and culminated in 2004; by 2005 the velocity had dropped to 40 m a−1. The positions of the terminus on maps from 1986, 1997 and 2004 show that the terminus must have advanced between 1986 and 1997 and again between 1997 and 2004, which is consistent with the above. There is anecdotal evidence that Sudurjökull has surged in the past (Reference Björnsson, Pálsson, Sigurðsson and FlowersBjörnsson and others, 2003) and it is also known from sediments in the lake in front of the terminus that Sudurjökull has been extremely dynamic (Reference Geirsdóttir, Miller, Wattrus, Björnsson and ThorsGeirsdsóttir and others, 2008).
The correlation between the InSAR and GPS data, shown in Figure 4, is 0.79 with a rms difference of 5 m a−1. Observations at locations on Hagafellsjökull Vestri were omitted, as ice flows in a direction for which the sensor had little sensitivity due to the acquisition geometry. In addition, the GPS data for this glacier show that, in 2001, the glacier velocity peaked 9.4 km from the margin at an elevation of 950 m and velocity was enhanced following a surge event of 1999, so agreement between the InSAR and GPS observations is not expected. That the smallest measurement uncertainties (±5 m a−1)are at the level of the rms difference between the InSAR and GPS velocities suggests that any seasonal or interannual variations in ice velocity between February1994 and summer 2001 are modest.
Fig. 4. Comparison of InSAR- and GPS-derived ice velocities for 13 locations on the ice cap, numbered as in Figure 2. Data from locations covered by dual-look InSAR are shown as squares; those for single-look coverage are shown as circles. Stake locations on Hagafellsjökull Vestri (1–8) are omitted – as agreement is not expected due to enhanced ice velocity in 2001 following a glacier surge in 1999 and the fact that the radar look direction is insensitive to flow. Location 11 was also omitted from the comparison, as no InSAR data were available within 500 m.
Conclusions
This research provides the first ice velocity map for LIC. The velocity data were derived from ERS SAR interferometry and the data were acquired between 22 and 27 February 1994. We have identified eight principal outlet glaciers, and the maximum speed recorded was 75 m a−1. Eight down-glacier velocity transects were extracted, along three of which we were able to compare our InSAR results with sparse surface velocity measurements determined from a GPS survey undertaken over 170 days during summer 2001. At six of the eleven locations included in both the GPS and InSAR datasets, ice velocity measurements were within error, indicating little change in ice velocity between February1994 and summer 2001. The largest difference (47 ± 10 m a−1 ) between the InSAR and GPS velocity datasets occurred at Hagafellsjökull Vestri (L4) and is attributed to locally high InSAR measurement error and the fact that, in 2001, ice velocity was elevated following a surge.
The close agreement between the GPS and InSAR datasets indicates that seasonal ice velocity variations at LIC are small, though non-zero velocities at the termini of four of the eight glaciers surveyed suggest that these glaciers were advancing in February 1994. Our data, in addition to other studies, suggest that Sudurjökull was experiencing a surge in 1994.
