Introduction

The aim of this paper is to present preliminary observations made of two rock glaciers on the sub-Antarctic island of South Georgia. Subsequent interpretation covers the possible origins and types of these rock glaciers.

Background

South Georgia is the largest island in the Scotia arc, lying about 1500 km to the north-east of the Antarctic Peninsula (Fig. 1). It is a narrow island, 170 km long, dominated by the mountains of the Allardyce and Salvesen Ranges which reach 2934 m (Mount Paget).

Fig. 1. Map showing location of rock glaciers with respect to the ice-free areas of South Georgia.

The climate of South Georgia is primarily determined by its position south of the Antarctic Convergence, in a zone of prevailing westerlies (Reference PepperPepper, 1954). However, the mountains impose a strong influence on local weather patterns which results in the west coast having much higher precipitation than the east coast (Reference SmithSmith, 1960[b]). Extreme maximum temperatures of 21 °C on the east coast are associated with föhn winds. The British Antarctic Survey scientific station at King Edward Point, located in the lee of the Allardyce Range, returned 5.6 oktas for average cloud cover and 1699 mm (water equivalent) for total precipitation in 1975. Mean monthly air temperatures for the period 1971–75 gave a maximum of +5.6°C in February and a minimum of −1.5 °C in June. The mean annual temperature in this area is +2.1 °C and this should be fairly representative of the north-eastern coastal area as a whole (Reference Richards and Tickellcf. Richards and Tickell, 1968). Geologically, South Georgia is a detached block of continental crust composed largely of turbidites of late Mesozoic age (Reference Bell, Bell, Mair and StoreyBell and others, 1977). A small igneous complex centres around Drygalski Fjord (Fig. 1). Both the igneous and sedimentary rock types have undergone severe deformation and are highly fractured. This makes them particularly susceptible to weathering (Reference SkidmoreSkidmore, 1972) and examples of catastrophic failure have been recorded (Reference Gordon, Gordon, Birnie and TimmisGordon and others, 1978).

About 58% of South Georgia is at present ice-covered (Reference SmithSmith, 1960[b]), with the bulk of the lower-lying ice-free areas restricted to the north-east coast (Fig. 1). Geomorphological mapping of these ice-free areas by members of the Department of Geography, University of Aberdeen, revealed a number of pro-talus landforms (Reference BirnieBirnie, unpublished). The majority of these were single ridge features but two examples of multi-ridge rock-glacier features were discovered. The first occupies the floor of a south-facing cirque, 2 km to the east of Hamilton Bay and overlooking Cooper Sound (Fig. 1). The second is developed on the south-east flanks of Binary Peaks in the Royal Bay area (Fig. 1). The rock glaciers are derived from igneous and sedimentary source rocks, respectively.

Cooper Sound Rock Glacier

The Cooper Sound rock glacier comprises a tongue-like mass of rock debris extending 1.5 km down-valley from beneath the cirque headwall, widening from 200 m at its head to 500 m at its terminus (Fig. 2). The feature lies between 200 m and 57 m a.s.l. (height determined with Reynolds aneroid type B373), and has an average surface slope of 12°. Many superficial ridges exist on the upper surface of the rock glacier. Near its head these run longitudinally but become transverse down-slope, with an arcuate plan form (Figs 2 and 3). Individual ridges are 5–8 m high and have steep slopes between 35° and 40° on their down-glacier sides.

Fig. 2. Location and geomorphic setting of Cooper Sound rock glacier. (Based on 1974 air photography by HMS Endurance). The arrow indicates the area behind the rock-glacier head which receives most rock debris.

Fig. 3. View south-west across the Cooper Sound rock glacier. The contributing rockwall lies off the photograph to the right. The reverse slope at the head of the feature and the most recent deposits (area 1) are clearly picked out by the lighter colour of the unweathered surface debris. The oldest deposits comprise a series of degraded ridges on the extreme left.

In general, the surface debris is coarse with a wide size range from less than 10 cm to several metres in diameter. Finer debris is only exposed along the steep slopes which occur around the margin of the rock glacier or on actively failing slopes on the upper surfaces. All the size components are angular and consist of mixed ultrabasic and basic rocks which reflect the variety of types exposed in the cirque headwall.

The rock glacier can be divided into four areas on the basis of morphological and vegetational differences (Fig. 2). In an attempt to determine vegetational differences, measurements were made of lichen thalli. The following procedure was adopted: sample sites were chosen near the middle (in terms of altitude) of each area; the largest thallus on 25 separate stones was measured; only the green lichens (Rhizocarpon sp., probably geographicum) were used and only those on clasts of feldspathic gabbro. Despite the attempts to eliminate errors due to local factors influencing lichen growth, the resulting lichen counts are likely to give an incomplete measure of age differences between sites (due to the effect of altitude on lichen growth), and are presented here purely as a guide to relative differences between the four areas of the rock glacier. The following descriptions of these areas also include other site attributes such as general vegetation cover and the thickness of weathering rinds on surface rocks. The characteristics of the four areas are as follows:

• (1) The upper part of the rock glacier lies between 200 m and 175 m a.s.l. The debris is characterized by a light grey colour reflecting its unweathered nature. The longitudinal surface ridges are angular in cross-profile and terminate at a distinct break of slope marked by a steep ramp. This ramp rides over the more weathered surface debris of area (2). The surface stones have no weathering rind and vegetation in this upper area is restricted to two kinds of crustose lichen, providing less than a 1% cover on most rocks. The lichen count gave a mean diameter of 2.8 cm with a range of 1.3–4.2 cm.

• (2) The second area lies below the ramp described above. It descends from 167 m to 119 m a.s.l. where another, less well-defined break in slope occurs. The ridges in this area are transverse and arcuate down-slope (Fig. 3). with more rounded cross-profiles than the ridges of area (1). The surface stones have a grey weathering rind, generally less than 1 mm thick. At least three different kinds of crustose lichen are common, covering up to 25% of individual rock surfaces, and mosses are present in a few sheltered niches. The lichen count gave a mean diameter of 4.8 cm with a range of 3.7–6.0 cm.

• (3) Below the break of slope beneath area (2), the surface ridges are still transverse but are lower and have more rounded cross-profiles than area (2). The vegetation cover is up to 75%, comprising a moss and lichen community. Whereas individual lichen thalli are identifiable in areas (1) and (2), here the encrustations interdigitate. Weathering rinds are generally over 1 mm thick and are sufficiently well developed to obscure lithological differences in the surface rocks. The lichen count gave a mean diameter of 4.7 cm with a range of 3.5–5.9 cm.

• (4) The outer limits of the rock glacier comprise a series of degraded, transverse ridges, between 2 m and 6 m high and well vegetated. These extend from 100 m down to 57 m a.s.l. and at some points these ridges are being undercut by the marine-cut cliffs below. Sections at the top of these cliffs reveal that the ridge debris overlies a sequence of till deposits. The vegetation cover on the outer ridges is almost 100% with a greater diversity of species than on the higher areas, although mosses and lichens still dominate. Tussock grass (Poa flabellata) grows on the outermost ridges. Surface rocks are well weathered with rinds over 1 mm thick. The lichen count gave a mean diameter of 4.8 cm with a range of 3.9–5.9 cm.

Most of the upper part of the rock glacier is at present separated from the cirque headwall by a depression about 20 m deep, 200 m across and up to 150 m wide. The slope leading down into this depression from the head of the rock glacier stands at 38° and was observed to be actively failing in March 1976. Only at the extreme eastern edge is the head of the rock glacier attached to the talus below the headwall (Fig. 2).

The cirque headwall adjacent to the head of the rock glacier is approximately 250 m high and is cut by a complex gully system which leads into three major chutes. These chutes direct rockfalls along a 100 m length of cliff foot which lies directly behind the head of the rock glacier (Fig. 2).

Interpretation

Two main types of rock glacier have been identified in alpine areas; these are the “ice-cemented” and “ice-cored” types (Reference PotterPotter, 1972, p. 3027). The first appears to develop as a result of the flow of talus with interstitial ice, and requires that the climate be cold enough for permafrost to exist (Reference WashburnWashburn, 1973). On the other hand, the “ice-cored” rock glacier is thought to develop as a result of glacier ice becoming covered with rock debris and its development depends on the initial existence of a glacier, the volume of debris supply, and the rate of glacier ablation, rather than purely climatic conditions (Reference WhalleyWhalley, 1974). Thus, “ice-cored” rock glaciers may occur in environments with a mean annual temperature (MAT) above 0 °C, and examples have been recorded in the Akureyri area of north Iceland where the MAT is +4 °C.

Although the two main types of rock glacier have different origins, they may be morphologically similar (Reference CorteCorte, 1976; Reference WhiteWhite, 1976). This is thought to be especially true where they occur as relict features. However, studies on active rock glaciers, for example, in the western Yukon, indicate that features like saucer-shaped depressions at the rock-glacier head, lateral longitudinal furrows, central meandering furrows, and collapse pits may be indicative of ice cores (Reference Vernon and HughesVernon and Hughes, 1966).

Morphological features associated with the Cooper Sound rock glacier suggest that it is of the ice-cored type. In particular, the deep depression between the rock-glacier head and the cirque walls behind may indicate the former presence of a glacier. This depression is similar to those described behind ice-cored rock glaciers elsewhere (Reference WhiteWhite, 1976). Although no direct evidence for the presence of an ice core was observed in the field, the activity and steepness of many of the debris slopes on and around the Cooper Sound rock glacier indicate inherent instability which may be the result of an ice core moving or melting out. Lack of melt-water activity suggests the former is more likely.

At the present time, the Cooper Sound rock glacier is “relict”, at least in terms of debris supply, since a depression separates the head of the feature from the debris sources above (Fig. 2). Although it is possible that debris supply is achieved over an annual snow-pack which fills the depression during spring and early summer, the depth of snow required makes it unlikely, especially when altitude and southerly aspect are taken into account. The depression was unfilled when air photographs were taken by a helicopter from HMS Endurance in November 1974 (RN 13/74 Unclassified). It is more likely that a perennial snow/ice body did occupy the depression during a colder period but has since melted.

The possible effect of climatic change makes it worthwhile examining the alternative hypothesis that the rock glacier originated from frozen talus. If this is the case, permafrost conditions should have existed at least in the area of its source. Typical figures for dry and saturated adiabatic lapse-rates are l.0deg/l00m and 0.6 deg/100m (Reference LaaksonenLaaksonen, 1976), respectively, and Reference SmithSmith (1960[b]) gave a figure of 0.7deg/100m for the lapse-rate in the Cumberland Bay area of South Georgia. Given that the MAT is around 2.1 °C, the altitude of permafrost in South Georgia at present is, at a minimum, around 200 m but is more likely to be near 300 m. The altitude of the head of the Cooper Sound rock glacier is 200 m, probably below the lower limit of permafrost at present. However, taking into account local effects such as aspect, it is possible that a 1–2 deg drop in MAT could create the conditions required for an ice-cemented rock glacier to develop. Thus, only a slight change from present climatic conditions could permit an ice-cemented rock glacier to develop at the altitude of the head of the Cooper Sound example.

Despite the above argument, an origin from the flow of frozen talus is not thought to be valid for the Cooper Sound rock glacier, because of the spatial separation that exists between the head of the rock glacier and the source talus. Since ice cemented rock glaciers develop directly from frozen talus and are contiguous with it, the separation is more likely to be due to the former presence of an ice mass. Thus it is on morphological rather than climatic grounds that the Cooper Sound rock glacier is thought to be of the ice-cored type.

In this particular location, burial of glacier ice may be explained by a high potential debris supply from the dissected cirque headwall behind, and the restricted length of cliff foot receiving this debris. Comparison between potential debris source areas and area of receiving glacier has been made for several depositional landforms in the Cooper Bay–Hamilton Bay area (Reference BirnieBirnie, unpublished). These include a range of features from pro-talus ramparts to ice-cored moraines. The results suggest that the fundamental constraints to rock-glacier development are:

• (1) Contributing cliff area, which appears to determine debris supply.

• (2) The area of the receiving glacier.

The combination of small glacier and high potential supply of debris at the rock-glacier site appears to be unique in the Cooper Bay–Hamilton Bay area. One particular factor here is the complex gully system in the cirque headwall, which greatly increases the potential generating area. This is to be compared with the planar cliff faces contributing debris to several of the pro-talus ramparts (Fig. 2). These conclusions are comparable to those of Whalley (1974), who showed that the development of a rock glacier from Arapaho South Glacier in Colorado was due to the high volume of debris supply it received per unit area.

Development Chronology

The development of the Cooper Bay rock glacier appears to have taken place in four phases, shown by the four distinct morphological units identified within the feature. In addition, the presence of till beneath the outermost ridges indicates that the cirque which the rock glacier now occupies was previously occupied by an ice glacier.

Reference Clapperton, Clapperton, Sugden, Birnie, Hanson, Thom and Zinderen BakkerClapperton and others (1978) identified four glacial stages in South Georgia:

• (1) An ice-cap glaciation extending beyond the present coastline, with a maximum 17000 years B.P. (T₄).

• (2) A more limited “valley glaciation” occurring before 10000 years B.P. (T₃) and reaching up to 5 km beyond the present ice margins.

• (3) and (4) Two minor Neoglacial advances with maximum extents 200 years B.P. (T₂) and 24 years B.P. (T₁) of less than 1 km beyond present.

Rock glacier development is complex and depends not only on climatic factors but also on those governing debris supply and the flow of rock/ice admixes. This limits any direct correlation of rock-glacier development with glacial history. It is, however, possible to suggest that, in view of the extensive ice cover on South Georgia during the ice-cap and valley-glacier stages, it is likely that the till exposed beneath the outer ridges of the Cooper Bay rock glacier is a correlative of at least one of these stages. If this is the case, it is likely that this rock glacier has developed within the last 10000–17000 years. Until a properly calibrated lichen-growth curve is established for South Georgia, more accurate dating is not possible, although in view of the extremely degraded nature of the outer ridges of the feature, it is not considered possible that this rock glacier has developed solely in association with the most recent climatic fluctuation of the last 200 years.

Binary Peaks Rock Glacier

The Binary Peaks rock glacier is developed down-slope from a talus apron (Fig. 4) between 80 and 100 m long, and about 100 m high. Above the talus is a cliff face between 5 m and 20 m high. The rock glacier is lobate (Fig. 5) and is composed of fragments of greywacke up to 4.5 m in diameter, but fragments over 2 m are rare. The most common visible size ranges are 30–50 cm and 100–200 cm. Fine-size components were not observed.

Fig. 4. Location and geomorphic setting of the Binary Peaks rock glacier (based partly on 182/500/2/70 of 42 Survey Engineer Regiment).

Fig. 5. View south-east across the Binary Peaks rock glacier. The feature occupies the foreground and the flow direction is from right to left.

The main surface features of the Binary Peaks rock glacier are a series of at least nine arcuate ridges from 3 m to 6 m high, with steeper distal slopes of between 21° and 37°. The ridges outside the one marked y on Figure 4 are degraded and over-riden at the south-western edge by the moraine of a former cirque glacier (Fig. 4). Thus two distinct ridge types are defined morphologically. No vegetation or weathering-rind data were collected.

The toe of the rock glacier lies at 363 m a.s.l. and it is 175 m long. The height difference between the head and the terminus is 41 m. Above the highest ramp the average surface slope is 9°.

Interpretation

The Binary Peaks rock glacier differs from the Cooper Sound feature both in terms of shape and relationship to rockwall sources. Whereas the Cooper Sound rock glacier is of the “spatulate” type recognized by White (1976), the Binary Peaks example is more akin to White’s “lobate” type which commonly occurs below talus. Indeed, the Binary Peaks feature, unlike the Cooper Sound one, is directly linked to the talus at present. This, together with the more simple morphology of the Binary Peaks rock glacier, suggests that it may be an example of an “ice-cemented” type (Reference PotterPotter, 1972).

In December 1976, excavation revealed ground ice 25 cm below the surface of frost-sorted till, about 200 m from the Binary Peaks rock glacier and at approximately the same altitude as its toe (360 m). Although permafrost does not occur at low levels in South Georgia (Reference SmithSmith, 1960[a]; Reference ThomThom, unpublished), given the altitude of this site, in relation to a freezing level of between 200 and 300 m mentioned previously, it is likely that this was perennial rather than seasonal ground ice. It would seem fair therefore to assume that, although comprising different sediment, permafrost would also occur at depth in the Binary Peaks rock glacier.

These observations, together with the lack of surface features considered diagnostic of the presence of an ice core, and the fact that the rock glacier is contiguous with the talus, suggest it may be “ice-cemented”. Such an origin may partly explain the order-of-magnitude size difference between it and the Cooper Sound example.

Development Chronology

The morphological characteristics of the Binary Peaks rock glacier described above suggest that it has experienced two phases of development. The outermost ridges have at one time been overtopped by till from an adjacent glacier. On the basis of spatial association, this till is dated as being from the 200 years B.P. (T₂) glacial advance. Therefore, the outer part of the rock glacier is older than this.

The outermost ridges rest on till. This till is spatially contiguous with deposits of the “valley glacial” phase (T₃) of glacial activity and is therefore dated as being pre-10000 years B.P. Thus the stratigraphical relations of the outer ridges of the Binary Peaks rock glacier suggest that the initial development of the feature occurred post-”valley glaciation”(T₃) but pre-200 years B.P. (T₂).

Conclusion

The presence of these rock glaciers in the maritime environment of South Georgia is contrary to some published views on rock-glacier distribution. For example, it has been stated that “both rock glaciers and ice-cored moraines are prevalent in glaciated or glacierized areas where the climate is somewhat continental” (Reference ØstremØstrem, 1964; Reference GuiterGuiter, 1972). Both forms are rare where the “climate is maritime” (from Whalley, 1974). However, the observations in South Georgia are not entirely unpredictable. It has been suggested here and elsewhere (Whalley, 1974) that the conditions required to initiate “ice-cored” rock-glacier development are high debris supply coupled with low receiving glacier area. For example, the Cooper Sound rock glacier is thought to have developed as a response to an extensive cliff–gully system debouching material along a restricted length of cliff foot. These observations confirm the theory that the juxtaposition of “large” cliffs and small glaciers may happen in any glaciated environment irrespective of zonal climate, and one possible explanation for the rarity of rock glaciers in any environment is the lack of suitable niches of this type.