Satellite imagery

To identify plume-polynyas, calving episodes, terminus positions, and supraglacial water storage at Helheim Glacier from 2011 to 2019, we used high-resolution satellite imagery from the Maxar (previously DigitalGlobe) constellation (WorldView-1, -2, and -3; QuickBird; IKONOS; and GeoEye-1), as well as Sentinel-2 and Landsat-8 optical satellite imagery (see Table S1 in the Supplementary material). This time period was chosen due to the density of high-resolution satellite imagery available. Top-of-atmosphere reflectance was calculated for all images. The spatial resolution of Maxar, Sentinel-2, and Landsat-8 imagery was 0.31–3.2, 10, and 15–30 m, respectively (Table S1). The typical time between successive usable Maxar images ranged from a couple of days to several months, while for Landsat-8 and Sentinel-2 the typical range was a couple of days to several weeks. The larger gaps occurred due to cloud cover and dark conditions.

Time-lapse imagery

A single time-lapse camera (StarDot Netcam SC, 5 megapixels), operated by the Cold Regions Research and Engineering Laboratory (CRREL) and positioned just south of Helheim Glacier (66.33° N, 38.174° W) (Fig. 1b), captured images of the terminus from July 2014 through August 2016. This original camera produced 450 images. CRREL then replaced this camera with a dual-camera system of the same camera type. These two cameras both point at the terminus of Helheim Glacier, but one points up-fjord and one down-fjord, enabling visualization of the terminus even as the glacier advances and retreats. Each camera produced 5172 images from the time they were installed in August 2016 through November 2019. The photo interval for all cameras was 3 h, but there were often longer intervals between usable images due to low-light and cloudy/foggy conditions. Nevertheless, in combining the time-lapse imagery with satellite imagery, we were able to increase the temporal resolution of our plume-polynya and calving time series.

Plume-polynya detection

The mélange was intact in all images throughout the study period, so plume-polynyas were visible in satellite and time-lapse imagery as areas of open water surrounded by mélange directly in front of the glacial terminus (Fig. 1). Time-lapse imagery was ideal for determining the existence and duration of plume-polynyas, while satellite imagery supplemented these observations and confirmed plume-polynyas which were very small or obscured by either icebergs in the mélange or the terminus geometry, relative to camera position. We also used satellite imagery to observe plume-polynyas from 2011 to mid-2014, before time-lapse imagery was available, and to map their locations. The lower spatial resolution of Landsat-8 and Sentinel-2 images meant that they were inadequate for observing small plume-polynyas, so a time was marked ‘no plume-polynya’ only if no plume-polynyas were visible in either time-lapse or Maxar imagery.

Calving timing and type

We manually examined successive imagery frame-by-frame to document the timing of calving episodes and iceberg type produced. All clear observations of visible terminus retreat between two consecutive images were attributed to full-thickness calving. Small collapses of the subaerial terminus and purely submarine calving were not observed due to the image resolution. Calving types were distinguished by the iceberg type produced during terminus retreat, as in Kehrl and others (Reference Kehrl, Joughin, Shean, Floricioiu and Krieger2017). Calved tabular icebergs were distinctive due to their rough surface and constant height above the mélange, whereas non-tabular icebergs often broke up and could rarely be identified in the mélange (Fig. 2). Calving episodes were classified into three types: (1) tabular calving, when a tabular iceberg appeared at the terminus and visually accounted for the entire terminus retreat observed; (2) mixed calving, when a tabular iceberg was visible at the terminus but could not visually account for the entire retreat; and (3) non-tabular calving, when terminus retreat occurred without producing a visible tabular iceberg. We refer to calving activity as ‘episodes’ instead of ‘events’ as it is unclear whether observed calving occurred as one event or many events during the time between two successive images (Kehrl and others, Reference Kehrl, Joughin, Shean, Floricioiu and Krieger2017).

Fig. 2. Image pairs depicting the difference between non-tabular calving (a, b) and mixed/tabular calving (c, d), as observed in time-lapse imagery. Times are in UTC. Note the terminus-parallel rifting/crevassing before both types of calving (a, c) and the terminus retreat after calving (b, d). A large tabular iceberg is visible in (d), but no distinctive icebergs can be observed in (b). Because the tabular iceberg in (d) does not account for the entire terminus retreat, this is a mixed calving episode.

We used the satellite-derived calving record of Kehrl and others (Reference Kehrl, Joughin, Shean, Floricioiu and Krieger2017) for 2011 through mid-2014 – before the first time-lapse camera was installed. From mid-2014 to mid-2016 (the end of the Kehrl and others record), we validated and supplemented our time-lapse data with their data. The use of both satellite and time-lapse images enabled us to cross-check observations from different perspectives, which was especially critical for processes occurring toward the far north end of the terminus where time-lapse image quality was lower.

Terminus position

Terminus position was measured from satellite imagery to provide context into advance and retreat patterns of Helheim Glacier. We manually digitized 388 terminus positions from March 2011 to December 2019, then calculated the area within a standard open-ended box behind each digitized terminus and divided this by the width. This method, which generates width-averaged measures of changes in terminus position, was established by Schild and Hamilton (Reference Schild and Hamilton2013) based on Moon and Joughin (Reference Moon and Joughin2008) and Howat and others (Reference Howat, Joughin, Fahnestock, Smith and Scambos2008).

Supraglacial meltwater

To compare the plume-polynya time series with supraglacial meltwater storage and release, we investigated the timing of water pooling on the surface of Helheim Glacier. In addition to the supraglacial lake (L) described by Everett and others (Reference Everett2016), we observed three areas in the highly crevassed downglacier region that regularly filled with supraglacial meltwater each summer (Fig. 3).

Fig. 3. Surface meltwater pooling visualized in true-color QuickBird imagery captured on 24 August 2011 (© 2011 Maxar Technologies, Inc.). (a) The regions of interest – L, C1, C2, and C3 – are marked and labeled in black, red, blue, and cyan, respectively. Pan-sharpened true-color Maxar imagery reveals morphological details of the supraglacial lake (b) and meltwater-filled crevasse areas C1 (c), C2 (d), and C3 (e). In this particular image, all areas contain pools of supraglacial water, yet none are filled to the maximum meltwater capacity observed in other images.

The surface area of meltwater is a proxy for water volume stored on the glacier surface. Surface area is unlikely to vary linearly with water volume in deep, narrow crevasses and would not be appropriate for estimating water budgets, but it is a suitable measurable parameter for our focus on the timing of filling and draining (e.g. Danielson and Sharp, Reference Danielson and Sharp2013). To calculate the area of water in each study area, we relied on the spectral differences between supraglacial water and bare glacial ice in satellite imagery (Fig. S1). To increase the spatial resolution of multispectral Landsat-8 images while preserving the spectral characteristics, multispectral bands were pan-sharpened to 15 m resolution using the Gram–Schmidt spectral-sharpening algorithm (Laben and Brower, Reference Laben and Brower2000). Then, the normalized difference water index for ice (NDWI_ice) was calculated (Fig. S1b). NDWI_ice, developed by Yang and Smith (Reference Yang and Smith2013), is a normalized ratio of the red and blue bands:

(1)$${\rm NDWI_{ice}} = \displaystyle{{BLUE-RED} \over {BLUE + RED}}, \;$$

where BLUE and RED are the spectral reflectivities of these wavelengths measured in the blue and red bands of the imagery.

NDWI_ice was calculated for cloud-free satellite imagery. Both Sentinel-2 and pan-sharpened Landsat-8 imagery clearly showed the timing of surface water storage with greater temporal resolution than Maxar imagery. Sentinel-2 imagery was ideal because it required less processing than Landsat-8 (no pan-sharpening). We therefore utilized Sentinel-2 when imagery was available (2016–19), Landsat-8 imagery before that when available (2013–15), and Maxar imagery before either Sentinel-2 or Landsat-8 were launched. One type of satellite imagery was used for each time interval.

We determined NDWI_ice thresholds to classify images into water and water-free regions (Fig. S1c). Both shadows and slush on the glacier surface complicated this process, as shadowed ice and slush have high NDWI_ice values similar to those of water. We decided to use two different thresholds: one more liberal threshold for the lake to identify as many water pixels as possible; and one narrower threshold for the crevasse regions, which were often more shadowed due to greater topographic relief. Different thresholds were also used for Sentinel-2, Landsat-8, and Maxar imagery. These threshold choices were made by comparing the NDWI_ice values of pixels manually identified as water versus ice in the areas of interest, to produce water classification results that matched those obtained by manually identifying the water areas. NDWI_ice thresholds for L (C1, C2, and C3) were 0.11 (0.21), 0.08 (0.11), and 0.22 (0.35) for Sentinel-2, Landsat-8, and Maxar, respectively.

After applying these thresholds, the rasters were clipped to the shapefile areas of interest. These areas remained consistent throughout the study period and across different satellite imagery products. The number of ‘water’ pixels in each area was multiplied by pixel area to calculate the surface area of water present in each area through time.

Subglacial hydraulic potential

To establish where water was routed subglacially and compare this with plume-polynya and surface water locations, we combined bed and surface topography into a numerical model for subglacial hydraulic potential. Gradients in subglacial hydraulic potential govern the flow routing of basal water (Shreve, Reference Shreve1972). We calculated subglacial hydraulic potential (Φ) as:

(2)$$\Phi = k\rho _{\rm i}{\boldsymbol g}( h-z) + \rho _{\rm w}{\boldsymbol g}z, \;$$

where ρ _i and ρ _w are the density of ice (917 kg m⁻³) and water (1000 kg m⁻³), respectively; g is the acceleration due to gravity (9.18 m s⁻²); h and z are the ice surface and bed elevations, respectively; and k is the cryostatic pressure factor (as in Everett and others (Reference Everett2016) and How and others (Reference How2017)). k is a fraction of ice-overburden pressure and is often set to 1, which assumes the catchment is at overburden pressure.

For the ice surface and bed elevations, we used the 150 m spatial resolution IceBridge BedMachine Greenland Version 3 surface and bed digital elevation models (DEMs) (Morlighem and others, Reference Morlighem2017). We calculated subglacial hydraulic potential over a range of k values from 0.9 to 1.2 to represent a range of overburden fractions likely present at the glacier bed over time and space (Everett and others, Reference Everett2016). Sinks in the hydropotential surface rasters were filled, then flow direction and flow accumulation (accumulated weight of upslope cells that flow into each downslope cell) were calculated with the D-infinity flow method (Tarboton, Reference Tarboton1997). We then passed a 3 × 3 low-pass filter over the flow accumulation data to smooth flow-routing lines.

Plume-polynya locations and timing

Plume-polynyas consistently surfaced near the center of the terminus, even as the terminus advanced and retreated several kilometers. Notably, most plume-polynyas were ~1.2 km northeast of the suture zone along the terminus (Fig. 9), similar to plume positions determined by Everett and others (Reference Everett, Murray, Selmes, Holland and Reeve2021). However, two plume-polynyas (12 September 2011 and 29 July 2014) were only ~300 m from the suture zone, ~900 m south-southwest of the others (consistent with the location of the plume observed by Everett and others (Reference Everett, Murray, Selmes, Holland and Reeve2021) in late July 2014). In addition, all the plume-polynyas visible in 2019 were ~200 m south-southwest of the previous line of plume-polynyas, closer to the suture zone (Fig. 9).

Fig. 9. Locations and visualizations of plumes surfacing as plume-polynyas at the terminus of Helheim Glacier. (a) Colored circles depict locations of all 21 plume-polynyas observed in satellite imagery from 2011 to 2019, and lines represent the corresponding terminus positions. Background panchromatic WorldView-1 imagery was acquired on 24 June 2012 (© 2012 Maxar Technologies, Inc.). Panchromatic imagery shows detailed morphology of plume-polynyas on (b) 16 April 2017 (WorldView-2); (c) 2 July 2014 (WorldView-2); and (d) 24 June 2012 (WorldView-1), © 2017, 2014, and 2012 Maxar Technologies, Inc.

Although the satellite imagery often provided just a few snapshots of the surfacing plumes, the time-lapse imagery allowed observations of plume-polynya changes through time and the duration of their persistence. We observed 24 plume-polynyas in total, 11 of which were in 2019 (Table 1). No plume-polynyas were detected in 2013 or 2018, though for 2013 this was due to poor data coverage (see Everett and others (Reference Everett, Murray, Selmes, Holland and Reeve2021) for information on 2013 plumes). Plume-polynya duration ranged from 1 to 29 d. Although the plumes primarily surfaced during the summer from late-June through September, eight plume-polynyas were visible at other times (mid-April, May, early-June, and early-October) (Table 1). Where plume-polynya data overlap, our plume record is completely consistent with that of Everett and others (Reference Everett, Murray, Selmes, Holland and Reeve2021).

Table 1. Dates of plume-polynya appearance observed from satellite and time-lapse imagery, duration of plume-polynya visibility from time-lapse imagery, and dates of the next calving episode after plume-polynya disappearance

Superscripts M, L, and S indicate Maxar, Landsat-8, and Sentinel-2 satellite imagery, respectively.

Calving

Of 200 full-thickness calving episodes classified from 2011 through 2019, 169 (84.5%) were non-tabular, 22 (11%) were mixed, and 9 (4.5%) were tabular (Figs 4–8). These data are, however, limited by few winter observations. Tabular calving generally occurred during winter or spring, or when the terminus was in an advanced state (as in mid-2011). Mixed calving episodes occurred throughout the year, and in 2016 and 2018 this type of calving was relatively more common. Non-tabular calving episodes, although more frequent in the summer, also occurred through all seasons.

Non-tabular calving often occurred in a succession of several distinct events along different areas of the terminus, consistent with the observations of Holland and others (Reference Holland2016). Calving sequences were distinguished by separate retreat along the northern and southern termini with a discontinuity near the suture zone. In some cases, icebergs calved from seemingly disconnected areas of the terminus at the same time (e.g. Figs 2a, b). Distinctive terminus-parallel rifting (consistent with ‘flexion zones’ in Murray and others, Reference Murray2015b) often preceded calving (e.g. Figs 2a, c). In mixed calving episodes, observed tabular icebergs were typically small and broke off the southern or northern terminus while non-tabular calving accomplished the primary terminus retreat. Nevertheless, we also observed several examples of distinctive large tabular icebergs in the mélange – sometimes calved during mixed episodes (e.g. Fig. 2d) and sometimes during purely tabular episodes.

Plume-polynyas and calving

Comparisons between the timing and characteristics of plume-polynyas and calving episodes reveal a relationship between the two processes. Although non-tabular calving occurred both before and immediately after plume-polynya appearance, no calving episodes large enough to cause visible terminus retreat occurred while a plume-polynya was visible, with only one exception (Figs 4a–8a). This one exception was on 16 April 2017, when a tabular iceberg calved from the far-northern terminus while a plume-polynya was visible at the center of the terminus (Fig. 10). Both the tabular iceberg and the plume-polynya are visible in the same satellite images, so we are sure that these events occurred concurrently but were separated spatially.

Fig. 10. Satellite imagery of the terminus of Helheim Glacier from 16 April 2017 depicting tabular calving at the northern terminus while a plume-polynya is observed at the center of the terminus. (a) True-color Landsat-8 image, with black box indicating the extent of (b). (b) True-color WorldView-2 image (© 2017 Maxar Technologies, Inc.). Note the plume-polynya in the cyan dashed circle and tabular iceberg to the north.

Crevasses and surface slumping typically appeared at the glacial terminus directly south of the plume-polynyas (e.g. Figs 11a, b). This apparent slumping could be failure along a slope from the surface to the waterline, as described by Parizek and others (Reference Parizek2019). Interestingly, non-tabular calving episodes often coincided with (within the time between successive images) or followed each plume-polynya's disappearance, accompanied by terminus retreat either directly south of where the plume-polynya had been (e.g. Fig. 11c) or across most of the terminus. Of the 18 plume-polynyas observed in the 2015–19 time-lapse imagery, 11 were followed by calving on either the same day as their disappearance or the next day (Table 1). Calving occurred 2–3 d after two of these plume-polynyas disappeared and over a week after five other plume-polynyas disappeared.

Fig. 11. Consecutive time-lapse images from 18 July 2017, captured at 06:00 (a), 09:00 (b), and 12:00 (c). Times are in UTC. Images depict a surfacing meltwater plume (cyan dashed oval) with crevassing (red dashed line) to the south (a), followed by the plume's disappearance (b), then terminus retreat due to non-tabular calving in the south (c).

Terminus advance and retreat

The terminus of Helheim Glacier retreated and re-advanced seasonally. This annual cycle of summer retreats and winter advances consisted of terminus position fluctuations of up to ~3–3.5 km (Fig. 4b). Superimposed on this was an overall trend of terminus retreat. The most advanced terminus position measured was on 10 March 2011 (defined as zero), while the most retreated position was on 8 September 2019, when the terminus was >5.6 km behind the 10 March 2011 position (Fig. 4b). Much of this retreat occurred during the 2017 and 2019 summers, when the terminus retreated ~1.5 km beyond any previously observed positions (Figs 4b, 7b).

Supraglacial meltwater storage and release

The maximum surface area of water in L varied each year, ranging from 0.20 km² in 2018 to 0.57 km² in 2015 (Figs 4c–8c). The peak in L area typically occurred in June or July, and in 2015, 2016, 2017, and 2019 a second distinctive peak in L water area occurred in July, August, or September. The water area in C1, C2, and C3 ranged from 0–0.31, 0–0.55, and 0–0.15 km², respectively. Areas C1, C2, and C3 filled and drained roughly synchronously, yet in some years C3 peaked before C1 and C2. Typically, filling and draining of these downglacier crevassed regions occurred soon after or during the first drainage of L. The clearest deviation from this pattern was in 2018 when there was no distinctive peak in L area; L instead followed a similar filling and draining sequence as the crevasse areas (Fig. 7c). We also did not observe a difference in timing of L drainage compared to C1, C2, and C3 drainage from 2011 to 2013 (Fig. 5c), but this was perhaps due to insufficient data coverage, as Everett and others (Reference Everett2016) did observe L drainage before filling and draining of downglacier crevasse regions in these years.

When plume-polynyas appeared, it was generally after drainage of L and while C1, C2, and C3 crevasses contained measurable quantities of water (Figs 4c–8c). In 2018, when L area did not peak as in other years, no plume surfaced at the terminus of Helheim Glacier. Nevertheless, C1, C2, and C3 filled with water during summer 2018. In 2017, however, a plume-polynya appeared in April before surface water was visible in L or within any crevasse areas. Similarly, the first plume-polynya of 2019 appeared in early May while meltwater was just starting to collect on the surface.

Subglacial water flow

The subglacial hydraulic potential model identified areas of high flow accumulation as strong meltwater routing locations. Subglacial flow accumulation maps calculated with different k values (Fig. 12) show that the modeled subglacial flow was routed to one, two, or three prominent meltwater discharge locations, depending on the terminus position. Plume-polynya locations aligned well with the central discharge location (Fig. 12). Additionally, supraglacial meltwater pooling areas L, C1, C2, and C3 all aligned with areas where different modeled subglacial flow routing configurations converged at hydropotential lows, which represented locations of the main subglacial channels in the model.

Fig. 12. Shaded subglacial flow routes determined from flow accumulation calculations over hydraulic potential surfaces. Different values of k, representing different overburden fractions, produced different flow pathways – shaded in blue (k = 1.00), purple (k = 1.10), and green (k = 1.14). Contours of hydraulic potential (k = 1.00) with spacing intervals of 1 MPa (major) and 0.25 MPa (minor) overlie the flow paths. Supraglacial lake and water-filled crevasse areas are marked, and cyan circles at the terminus show plume-polynya locations, from Figure 9. The main map (a) depicts the three different flow configurations together, while they are depicted separately in (b), (c), and (d). The background is a true-color Sentinel-2 image from 7 May 2016. Slight differences in flow paths from those reported by Everett and others (Reference Everett2016) are likely due to differences in BedMachine versions (v3 here versus v2 in Everett and others (Reference Everett2016)).

At lower values of k (<0.99), hydraulic potential gradients were steeper, and flow was mostly confined to within bed troughs, with no strong flow between C1 and C2. When k was just below 1 (~0.99), flow redirected to cross between two bed troughs from near-C1 to mid-C2. Subglacial flow accumulation routing over a hydraulic potential surface calculated with k = 1.00 (Fig. 12b) was nearly identical to that when k = 0.99. As k increased above 1 (Figs 12b, c), hydraulic potential gradients decreased, and flow redirected more with smaller variations in k.