(a) Side-scan sonar

The main part of the under-water data is based on sonographs obtained by a Klein model 400 side-scan sonar (SSS). The SSS system consisted of three units: an under-water unit (the “fish”), a combined data, power, and tow cable, and a dual-channel graphic printer. The fish is a streamlined, hydrodynamically balanced body containing two sets of transducers. These transmit a 0.1 ms ultrasonic sinusoidal pulse at 100 kHz and then change to a receiving mode for a time interval determined by the range.

Most of the pulse energy is concentrated in two beams with 40° openings. For these experiments, the fish was arranged so that both beams faced the ice wall, looking up and down from the horizontal. The beam width is 1° in the direction of travel. The resolution is determined both by graphic capability and range. It was typically 2–4 m in these studies.

The plotted image has a linear time-scale with zero at the centre, and each returning signal is plotted on the paper according to the time it is received after the outgoing pulse. As the fish moves through the water, the adjacent scans form an acoustic image with one scale determined by the speed of the fish. Strength of the return signal determines darkness of the plotted image. A strong signal appears black. For angles of incidence ≠ 90°, the strength of the return signal depends upon the roughness of the ice at scales comparable with the wavelength of the acoustic pulse (0.015 m) (Reference Klepsvik and FossumKlepsvik and Fossum 1980).

The present system was not equipped with a correcting device, the scales along the two axes of the sonograph were different, and the return times gave a non-linear representation of the object. The sonograph therefore needs careful analysis to give a correct image. The sonographs may also be distorted by phenomena such as: (a) cross-talk of various kinds between the channels, (b) deviating fish motions, (c) multiple reflections, and (d) focusing of the sound beams.

Further descriptions of the SSS can be found in Reference LeenhardtLeenhardt (1974) and Reference FlemmingFlemming (1976). Information on this kind of SSS investigation of ice shapes has been given by Reference Klepsvik and FossumKlepsvik and Fossum (1980). Their studies on NARE 1978–79 led to the present programme.

Two profiling techniques were used in the present study. Most of the data, altogether 130 line km, were collected by towing the fish behind the vessel, usually at around 50 m from the ice face (Figs 1 and 2). The best results were obtained by close profiling. However, navigating the vessel at a constant short distance from the ice face was not feasible because of reduced manoeuvrability at the profiling speed of 2–3 knots. We found it possible to profile as close as 30 m along straight sections.

Fig. 1 Index map showing location of side-scan studies.

Fig. 2 Principle of horizontal, under-water sounding. The figure does not show the whole sector covered by the sound beam.

The fish was towed at several depths at most locations. A major difference between the present study and that of Reference Klepsvik and FossumKlepsvik and Fossum (1980) was that the present fish was now fitted with a depth sensor. This was read on board, and the depth controlled by adjusting cable length or vessel speed. More importantly, it became possible to combine different profiles to build three-dimensional images of the ice face. Such reconstructions are unfortunately labour intensive, because variations in scales caused by changes in speed and range meant that the assembly had to be done manually.

The offset of the fish causes problems both in field observations and later reconstructions. The fish trails behind the ship at cable lengths typically three times the depth, and will therefore only broadly follow the ship’s course. It was difficult to get close to the ice at greater depths, because the fish had to be kept clear of the under-water “noses”. (We did hit the ice with the fish and cable, without causing damage, which reflects on the smoothness of the under-water ice.) The increased offset, in combination with the back-sloping ice, unfortunately meant poor records from the greatest depths.

The fish was also used in a vertical mode, being lowered and raised by the cable. This technique had the advantage that it provided a direct visual representation of the face of the ice, which was readily interpreted. A disadvantage with our arrangement was that the fish hung freely. Thus, there could be gaps in the vertical records because the fish rotated around the cable so that both transducers faced away from the ice (Fig.3).

Fig. 3 Results of vertical sounding of two sides of iceberg Billie (B).

(a) Original record of initial (newly fractured) face, and rectified to a 1 : 1 scale.

(b) Original record of mature face, and rectified to a 1 : I scale. The spikes are not from the ice, but are probably caused by ship motion. Note vertical grooves at the side of the face, with the signal alternating between reflection and shadow. These are most noticeable between 21 m and 50 m depth.

Fig.3a and b show data from one channel. The fish rotated while being lowered and raised so that this channel did not always face the ice. For those sections where the other channel then faced the wall this recorded profile is shown. There are also gaps in the data where neither channel faced the ice.

(b) Direct soundings

Data on the under-water shapes were also collected by direct soundings. Most soundings were done from a small boat, using a plumb-line. This was not easy in rough seas. Soundings were also done by plumb-line from the bow of the expedition vessel, K/V Andenes, by nudging the ice front, but this was also a problematic procedure. We sounded all sections where we used the side-scan sonar. Altogether, 47 profiles were sounded. Typical examples of soundings are given in Fig.4.

Fig. 4 Examples of plumb-line soundings. The distance between each sounding was at 3–5 m, and the number of sounding points varies from 4–12 for the sections shown. The soundings were in all cases continued out to a vertical (or near-vertical) edge below which no bottom was encountered. All distances in meters.

Initial stage

• (a) The subaerial face. As explained earlier, freshly fractured faces were recognized in the open sea by the absence of the effects of wave-action. The profile of such newly ruptured faces appears approximately vertical and smooth on a scale of metres.

• (b) The submarine face. The initial under-water profile is essentially vertical, and appears smooth at our resolution of a few metres. Fig.3a shows the profile of a freshly formed face.

Formative (young) stage. 0.1-≈3 years

• (a) The subaerial face. High ice fronts are generally over-hanging, often accentuated by snow-drift cornices. Crevasses are often seen in the ice shelf a few metres in from the edge. The undercut at the water line typically extends 2–3 m inwards, and 0.5–1 m up into the ice (firn).

• (b) The submarine face. The upper part of the face is in the form of an approximately plane ramp sloping at high angles, usually >45°. The size of the ramp depends upon age. It extends from a few metres to a few tens of metres. The ramp starts about 5 m below the water line, and the maximum depth varies from 5–10 m to a few tens of metres. Below the ramp, the face is nearly vertical for a considerable depth, before sloping backwards below 100–150 m depth (Figs 4 and 5b).

Fig. 5 Rectified under-water profiles of (a) mature stage (Riiser-Larsenisen), and (b) formative stage (Brunt Ice Shelf). All distances in metres.

Mature stage, several years old

• (a) The subaerial face is like the formative stage described above.

• (b) The submarine face has an under-water ramp observed at Riiser-Larsenisen up to 60 m from the ice front. This corresponds to an average melt rate of about 10 m a⁻¹, from the lime of calving at this locality (higher if the melt rate at the nose is large). The slopes may be plane, concave, or convex, and are generally less steep than at the formative stage. The face has a prominent “nose” at around 50 in water depth, and below this the ice face slopes backwards at angles around 30°→45° (Figs 3b, 4 and 5a). Limited data from one locality suggest that the face is smoothed in the direction along the front, i.e. that the under-water back-melting is greatest on what were originally protruding cusps. This smoothing seems to increase with depth.

Processes governing the formation of the undercut face

Our observations indicate that ice fronts with a freeboard >20 m were practically always overhanging. The main reason must be undercutting at the water line and related crevassing of the ice shelf.

Three processes can contribute to the undercutting:

• (1) Higher local water velocities produced by waves and swell action cause higher effective heat-transfer rates between the ice and the near-surface waters, heated by short-wave radiation in the “summer”. Reference Martin, Josberger, Kauffman and HusseinyMartin and others (1978) showed that this was a very effective process, producing a 3 m wave cut in 1 day in ≈+2°C water.

• (2) Calved pieces of ice moved by the turbulent water cause mechanical erosion.

• (3) Ice and firn is wetted by splashing, causing lower albedos and hence under appropriate conditions more absorbed solar radiation.

These are mainly “summer” processes. Most of the year the sea ice effectively prevents turbulent motion, and in the winter the surface waters are also at freezing temperatures.

Only the first of these three processes can contribute to the deeper erosion of the submarine ramp observed in the formative and mature stages. The heat transfer seems to be very effective to 5 m depth. Below this the efficiency falls rapidly with depth.

Processes governing hack erosion at greater depths

The observations indicate varying degrees of melting with depth, with a minimum around 50–100 m depth, and a maximum annual melt of ≈10 m at 200 m depth. The heat transfer to the ice front depends upon the water temperature, and mixing coefficient and small-scale boundary-layer dynamics.

Field observations on the water temperatures show two phenomena:

• (1) In the summer, the upper ≈70 m of the water in contact with Riiser-Larsenisen are heated to about 0.5°C above the pressure melting-point (Reference Foldvik, Gammelsrød, Slotsvik and TørresenFoldvik and others 1985[a], Fig.15), with highest temperatures at the surface. Correspondingly, the above-freezing temperatures extend to 30—50 m depth along the Filchner-Ronne Ice Shelf (Reference Foldvik, Gammelsrød and TørresenFoldvik and others 1985[b], Figs 14 and 15). In the winter, the upper waters are at pressure melting-point. Hence, this condition leads to back melting to such depths in summer.

• (2) Foldvik and Kvinge (Reference Foldvik and Kvinge1974, Reference Foldvik, Kvinge and Dunbar1977) observed that the melting potential of water masses in contact with the Filchner Ice Shelf increases with depth, because the pressure melting-point decreases with depth (Fig.9). Temperatures were about 0.2°C above the pressure melting- point at 200 m depth. This condition should lead to melting which increases with depth from a minimum around 100 m, and takes place year-round.

  

  Fig. 9 Temperature and salinity of water near the Filchner Ice Shelf (lat. 77°44'S., long. 41°44'W.). The dashed line shows the change in pressure melting-point with depth for water of the salinity at lower levels. (From Reference Foldvik, Kvinge and DunbarFoldvik and Kvinge 1977.)

We therefore see that the combination of these temperature observations explains qualitatively the observed shapes as resulting from annual melting rates with a minimum around 50–100 m depth, and with greater annual melting at 200 m depth than near the surface.

Melting of vertical ice walls in the ocean has been discussed by Reference GillGill (1973), Reference Martin and KauffmanMartin and Kauffman (1977), Reference GadeGade (1979), Reference GreismanGreisman (1979), Reference HuppertHuppert (1980), and Reference Russell-HeadRussell-Head (1980). These give a range of melt-rates which bracket the rates presented here. The present observations give a melt-rate of 10 m a⁻¹ for a temperature difference (ΔT) above pressure melting-point of 0.2°C at 200 m depth, and a rate of 20 m a⁻¹ for a ΔT of 0.5°C, the latter derived from the observed rate of ≈5 m a⁻¹, and taking this to apply only for the summer period of 1/4 year. The differences between the various melt-rates proposed by the above authors are related to varying models for heat transfer to the ice face and are outside the theme of the present discussion.

The observed vertical ripples suggest vertically moving water and may confirm upwelling. Such processes, at various scales, have been proposed, e.g. by Reference NeshybaNeshyba (1977) and Reference JosbergerJosberger (1980), and would enhance melt-rates by their effect on the boundary-layer dynamics.

Observations from the closest comparable field situation are those of Reference HoldsworthHoldsworth (1982). He calculated a lateral melt-rate of 6–10 m a⁻¹ in -1.3°C water for the Erebus Glacier tongue, based on repeated mapping and calculated lateral creep spreading.

Many of the field observations presented here were anticipated by Reference RobinRobin (1979), who used the work of Foldvik and Kvinge (Reference Foldvik and Kvinge1974, Reference Foldvik, Kvinge and Dunbar1977) in a theoretical discussion of melting/freezing under, and in front of, ice shelves. He recognized the potential for increased melting with depth, and that this process could take place year-round, and he suggested a melt-rate at depth on the order of 10 m a⁻¹.

Buoyancy effects

As noted, even at the mature stage, the ice shelves are not generally up-warped at the front. Calculations show that profiles such as Figs 3b and 5 are essentially in balanced buoyancy, because the effect of the “nose” is compensated by the ice removed at greater depths.

Indeed, down-sloping towards the front is more commonly observed, and this is indirect confirmation of back-melting at depth, as recognized by Reference RobinRobin (1979). Such bending from the effect of extensive melting of the lowest ice could also increase the depth of the ramp.

Buoyancy probably accounts for the rough appearance of the mature face, causing large and small pieces of ice to “calve” off along faults and inhomogeneities (Fig.6). The face seems roughest at shallow depths and such calving is presumably assisted by wave and swell action.

Under-water plastic deformation

A protruding under-water “nose” will experience deformation as a result of the buoyancy stresses. Taking as a first approximation that the ice will begin to deform rapidly at a shear stress of 100 kPa (1 bar), we see that the shape of a “nose” extending 50 m as in Fig.3b or Fig.5a will be determined by the melt-rates, as these shapes will have maximum shear stresses less than 50 kPa at the line of the vertical wall, The shear stress increases with extension of the nose, and a 100 m nose could experience rapid plastic deformation. Thus plastic flow will limit the extension of the nose to approximately 100 m.