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Observations on Speke Glacier, Ruwenzori Range, Uganda

Published online by Cambridge University Press:  20 January 2017

Georg Kaser  and
Bernd Noggler
Georg Kaser
Affiliation:
Department of Geography, University of Innsbruck, A-6020 Innsbruck, Austria
Bernd Noggler
Affiliation:
Department of Geography, University of Innsbruck, A-6020 Innsbruck, Austria
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Abstract

Speke Glacier, the best studied and largest single glacier in the Ruwenzori Range (Uganda, East Africa), was revisited in January 1990. A comparison of its present state with former observations reveals that its terminus receded 35–45 m between 1958 and 1977; since 1977 it has retreated more than 150 m. Nearly half the width of the snout has been lost, mainly on its western side, and the entire western section of the south-facing glacier has shrunk substantially. The observed fluctuation conforms with changes occurring on other tropical glaciers. Explanations concerning the reasons for the glacier recession are presented.

Type
Research Article
Information
Journal of Glaciology , Volume 37 , Issue 127 , 1991 , pp. 313 - 318
Copyright
Copyright © International Glaciological Society 1991

Introduction

Mount Speke (4890 m) is one of the six ice-capped mountains of the Ruwenzori Range, Uganda, situated at approximately 0° 30′N, 30° E (Fig. 1). The mountain range reaches its highest elevation of 5109 m on Margherita Peak, Mount Stanley, and the lowest recent glacier terminus positions are located below 4400 m.

Fig. 1. The ice-covered mountains of the central Ruwenzori, Uganda. Sp, Speke Glacier; El, Elena Glacier; Sa, Savoia Glacier; M, Moore Glacier (after Reference Wielochowsky,Wielochowsky, 1989).

Reference Haeberli,, Bösch,, Scherler, Ostrem and WallénHaeberli and others (1989), citing Reference Messerli,Messerli (1980), identified 30 glacier units covering a total area of 4.96 km2, whereas Reference Hastenrath,Hastenrath (1984), citing Reference Whittow,Whittow and others (1963), Reference Temple,Temple (1968), Reference Osmaston, and Pasteur,Osmaston and Pasteur (1972), and his own observations in 1974 spoke of 44 separate ice bodies with an area of 3.9 km2. Reference Whittow,, Shepherd,, Goldthorpe and TempleWhittow and others (1963) recorded the existence of 37 Ruwenzori glaciers with a total glacier area of slightly less than 5 km2. Reference Whittow,, Shepherd,, Goldthorpe and TempleWhittow and others (1963) also reported snow-line altitudes of 15 000 ft (approximately 4570 m) on the eastern slopes and 15 600 ft (approximately 4750 m) on the western slopes, respectively.

The largest coherent ice bodies are the remnant summit ice caps on Mount Stanley and Mount Speke, whereas the largest single valley glacier is south-facing Speke Glacier of Mount Speke. Speke Glacier was the subject of our visit in January 1990.

Following the detailed reports of the exploration of Abruzzi’s expedition in 1906, including the excellent photographs of Vittorio Sella and the first valid topographical map of the Ruwenzori Range (Luigi Amadeo. Duke of the Abruzzi, 1909; Reference Fiory-Ceccopieri,Fiory-Ceccopieri, 1981), several reports of later Ruwenzori expeditions have yielded only an approximate knowledge about glacier recession (e.g. Reference Humphreys,Humphreys, 1927, Reference Humphreys,1933; Reference Menzies,Menzies, 1951).

The first serious glaciological studies were carried out by E. Bergström, a member of the British Ruwenzori Expedition 1952 (Reference Bergström,Bergström, 1955). He pointed out that two ablation periods per year during the so-called “dry” seasons of January—February and June-August and two wet seasons dominate the glacial regime on Ruwenzori. Intensive glaciological investigations were performed by the members of Makarere University College of Uganda on Elena and Savoia Glaciers of Mount Stanley, Moore Glacier of Mount Baker and Speke Glacier of Mount Speke during six expeditions between 1957 and 1961 (Reference Whittow,Whittow, 1959, Reference Whittow,1960; Reference Whittow,, Shepherd,, Goldthorpe and TempleWhittow and others, 1963). Reference Temple,Temple (1968) extended these investigations to 1967.

Comprehensive summaries of glaciological investigations on Ruwenzori and lists of pertinent literature, photographic comparisons and topographical maps have been given by Reference Whittow,, Shepherd,, Goldthorpe and TempleWhittow and others (1963), Reference Osmaston, and Pasteur,Osmaston and Pasteur (1972) and Reference Hastenrath,Hastenrath (1984). The most recent photographs of Ruwenzori glaciers include those of Hastenrath from 1974 (Reference Hastenrath,, Rostom, and CaukwellHastenrath, 1984) and Lichtenegger from 1977 (Reference Lichtenegger, and Lichtenegger,Lichtenegger and Lichtenegger, 1978).

Speke Glacier

Speke glacier is the largest and also the best studied glacier of Ruwenzori. According to Reference Whittow,, Shepherd,, Goldthorpe and TempleWhittow and others (1963), Speke Glacier covered an area of approximately 0.357 km2, reaching from the Mount Speke summit crest at 4814 m to the terminus at 4344 m. Assuming a permanent firn-line altitude of 4570 m, the accumulation area of the south-facing glacier was estimated to be twice as large as the ablation area.

In June 1958 and June 1959, cairns and stone markers were established immediately in front of the glacier tongue to facilitate measurements of terminus changes in June 1958, January 1959, June 1959, January 1960 (Reference Whittow,, Shepherd,, Goldthorpe and TempleWhittow and others, 1963), July 1961, March 1962, December 1962, December 1963 and January 1967 (Reference Temple,Temple, 1968). Between June 1958 and January 1967, a net recession of approximately 11 m was recorded. However, between July 1961 and March 1962 the terminus advanced by 3.5 m (Reference Temple,Temple, 1968). A similar advance was also observed at Elena Glacier. Reference Temple,Temple (1968) and Reference Osmaston, and Pasteur,Osmaston and Pasteur (1972) have suggested that increased precipitation was responsible for these advances.

Small advances of the eastern part of the glacier tongue were also observed between June 1958 and January 1959 and between June 1959 and January 1960.

As a result of these observations, Reference Whittow,, Shepherd,, Goldthorpe and TempleWhittow and others (1963) predicted that Speke Glacier would shrink to a small remnant ice body above 4600 m by the end of the century.

Observations and Results

Our initial impression of Speke Glacier during our visit in January 1990 was that of a generally shrunken glacier with a terminus that had undergone a significant retreat (Fig. 2). A lake measuring approximately 120 × 140 m had developed behind a ridge of solid rock in front of the glacier.

Fig. 2. Speke Glacier seen from point Ρ (see Fig. 5). Photograph taken by the authors on 29 January 1990.

Fig. 5. The terminus positions of Speke Glacier in 1950 (after Reference Menzies,Menzies, 1951), 1958 (after Reference Whittow,, Shepherd,, Goldthorpe and TempleWhittow and others, 1963) and January 1990. The figure is based on the map of Reference Whittow,, Shepherd,, Goldthorpe and TempleWhittow and others, 1963 p. 594).

Small moraines formed of rather large boulders deposited upon this ridge furnish evidence of the 1961–62 advance and, in comparison with the 1974 photograph of Reference Hastenrath,Hastenrath (1984), of an advance or at least a longer steady state around 1974. Behind this ridge no further signs of moraine formation were found. Reference Osmaston, and Pasteur,Osmaston and Pasteur (1972) explained the general lack of moraines as due to a combination of the hardness of the rock and temperature variations that are too small to cause significant rock shattering.

Between the above-mentioned moraines and the actual terminus no vegetation exists except a very few newly grown lichens.

A number of ice blocks dot the area between the glacier terminus and the lake. Evidently, the ice blocks are the result of a thinning-out process of the glacier tongue.

The two survey points of June 1958 and the one of June 1959 recorded on the map of Reference Whittow,, Shepherd,, Goldthorpe and TempleWhittow and others (1963) were easily located, and after searching for them, the painted stones B, C, D and G were rediscovered under a dense lichen cover. A comprehensive series of photographs was taken from different survey points, including a pair of stereo photographs of the glacier tongue. The distance between mark D and the actual terminus was tape-measured.

Figures 3 and 4 show the present and former tongue positions of Speke Glacier from different locations. The ice-front positions in June 1958, July 1961 and January 1974 were drawn with reference to comparable photographs published by Reference Whittow,, Shepherd,, Goldthorpe and TempleWhittow and others (1963) and Reference Hastenrath,Hastenrath (1984). The position of the glacier tongue in January 1967 (Reference Temple,Temple, 1968) which was situated midway between that of July 1961 and January 1974 is not shown for reasons of clarity.

Fig. 3. Terminus positions of Speke Glaner observed from survey point 2 (see Fig. 5). Solid line, June 1958; broken line, July 1961 (both after Reference Whittow,, Shepherd,, Goldthorpe and TempleWhittow and others, 1963); dotted line, January 1974 (after Reference Hastenrath,Hastenrath, 1984). Marks D (note the person sitting on the stone; the mark itself is hidden behind a plant), Β and C from left are circled. Photograph taken by the authors on 29 January 1990.

Fig. 4. Terminus positions of Speke Glacier as seen from survey point 1 (see Fig. 5). Lines and references are the same as in Figure 3. Mark G is circled. Photograph taken by the authors on 29 January 1990.

Figure 5, showing the retreat of the terminus of Speke Glacier between 1950 and 1990, is based on the map of Whittow and others (1963, p. 594). The 1990 situation was constructed on the basis of field notes, measured distances, lateral and frontal photographs as shown in Figures 2, 3 and 4 and the stereo photographs.

Figure 6 gives an overall view of Speke Glacier as seen from Albert Peak (5087 m) on Mount Stanley. The white line is bared as a comparison of photographs obtained in 1967 (Reference Temple,Temple, 1968), 1974 (Reference Hastenrath,Hastenrath, 1984) and 1977 (Reference Lichtenegger, and Lichtenegger,Lichtenegger and Lichtenegger, 1978). Although there were no distinguishable variations in the extent of the ice-covered surface between 1967 and 1977, a thinning of the western part of the seraczone occurred at approximately 4700 m. By 1990 this western seraczone had disappeared along with almost half the tongue on the western side of Speke Glacier. By contrast, the eastern part of the seraczone is still as thick and active as it was in 1967. A comparison of all four photographs taken between 1967 and 1990 gives the general impression of a very substantial shrinkage of the whole western section of Speke Glacier at the same time that the eastern section was maintaining an active state.

Fig. 6. Speke Glacier as seen from Albert Peak on Mount Stanley. The white line indicates the extent of Speke Glacier as reconstructed on the basis of photographs taken in 1967 (Reference Temple,Temple, 1968), 1974 (Reference Hastenrath,Hastenrath, 1984) and 1977 (Reference Lichtenegger, and Lichtenegger,Lichtenegger and Lichtenegger, 1978). During this period no marked variations in the extent of the ice could be seen from the photographs. Photograph taken by H. Wagner on 29 January 1990.

The prediction of Reference Whittow,, Shepherd,, Goldthorpe and TempleWhittow and others (1963) that Speke Glacier would shrink to a remnant ice body above 4600 m within this century is already being realized for the western section of Speke Glacier, while at the same time the eastern section has undergone minimal changes.

Variations in the terminus of Speke Glacier (referenced to mark D) are shown in Figure 7. Earlier data are taken from Reference Temple,Temple (1968) and Reference Hastenrath,Hastenrath (1984), whereas the 1977 value was reconstructed from a photograph published by Reference Lichtenegger, and Lichtenegger,Lichtenegger and Lichtenegger (1978). Reference Hastenrath,Hastenrath (1984) reported his assessment of a 3040 m retreat of the snout of Speke Glacier between 1958 and 1974, and a lateral shrinkage of 10–20 m in the same period. Compared to the 1974 state, a 5–10 m retreat was estimated by 1977. Although minor advances have occurred, Figure 7 shows a net recession of the terminus of approximately 45 m between 1958 and 1977 followed by a retreat of 150 m since then. Compared to its total length of 1 km (Reference Hastenrath,Hastenrath, 1984), the retreat of Speke Glacier since 1958 represents a loss of about 20%.

Fig. 7. Terminus fluctuations of Speke Glacier between January 1958 and January 1990 based on measurements from mark D (dots) (Reference Temple,Temple, 1968; data in this paper) and from assessments of photographs (triangles) (Reference Lichtenegger, and Lichtenegger,Lichtenegger and Lichtenegger, 1978; Reference Hastenrath,Hastenrath, 1984).

Discussion and Conclusions

The recent substantial retreat of Speke Glacier correlates well with observations elsewhere in the world and especially with those of tropical areas (Reference Allison,, Peterson,, Hope, Peterson, Radok and AllisonAllison and Peterson, 1976, Reference Allison, and Peterson,1989; Reference Hastenrath,Hastenrath, 1984; Reference Patzelt,Patzelt, 1987; Reference Hastenrath, and Kruss,Hastenrath and others, 1989; Reference Kaser,, Ames, and ZamoraKaser and others, 1990). In particular, the significant shrinkage of Speke Glacier since 1977 corresponds closely with the extreme mass loss observed on the similar-sized Lewis Glacier of Mount Kenya since 1974 (Reference Patzelt,, Schneider, and MoserPatzelt and others, 1985; Reference Hastenrath, and Kruss,Hastenrath and others, 1989).

Looking for the reasons of the fluctuations of tropical glaciers, Reference Patzelt,, Schneider, and MoserPatzelt and others (1985), and also Reference Kruss, and Hastenrath,Kruss and Hastenrath (1987), suggested that significant decreases in precipitation have caused the general recent glacier recession observed on Mount Kenya, which is also situated in tropical East Africa. Reference Temple,Temple (1968) suggested that increased amounts of precipitation, which are evident in the run-off records of Mubuku River and which were also reported by Reference Fantin,Fantin (1968) and by Reference Osmaston, and Pasteur,Osmaston and Pasteur (1972), caused the small advances of both Elena and Speke Glaciers around 1960. The fluctuations of glaciers in the Peruvian Cordillera Blanca correlate with observed change in both precipitation and air temperature (Reference Kaser,, Ames, and ZamoraKaser and others, 1990).

Assuming that the change of precipitation may be considered as controlling the general recession of Speke Glacier, this can hardly explain the differences in the behaviour of its entire western and eastern sections as shown in Figure 6. Spatial differences in the behaviour of the snout have already been observed and discussed by Reference Temple,Temple (1968) and the studies carried out on Mount Kenya by Kruss and Hastenrath (Reference Kruss, and Hastenrath,Kruss and Hastenrath, 1987; Reference Hastenrath, and Kruss,Hastenrath and Kruss, 1988; Reference Kruss, and Hastenrath,Kruss and Hastenrath, 1990) confirm Temple’s observations not only for the snout but also for the entire glacier.

A decrease in precipitation is normally associated with a decrease in vapour pressure and with decreased cloud cover. This leads to an increased amount of absorbed shortwave radiation, especially during the drier seasons. It is not only the varying degree of cloud cover that leads to local variance of absorbed solar radiation but variable topographic shading as well. The eastern section of Speke Glacier is protected against incident shortwave radiation for two reasons: in the morning by topographical shading and in the afternoon by convective cloud cover. In contrast to this, the western section receives much more solar radiation during the morning hours.

The precise reasons for the fluctuations of Speke Glacier will remain unresolved as long as the present lack of information on regional climate, mass balance and ice flow continues.

Acknowledgements

The authors thank H. Wagner for the photograph in Figure 6, S. Hastenrath, whose review resulted in a significant improvement in the clarity of this paper, and A.J. Gow and M. Kuhn, who improved the English.

The accuracy of references in the text and in this list is the responsiblity of the authors, to whom queries should be addressed.

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Figure 0

Fig. 1. The ice-covered mountains of the central Ruwenzori, Uganda. Sp, Speke Glacier; El, Elena Glacier; Sa, Savoia Glacier; M, Moore Glacier (after Wielochowsky, 1989).

Figure 1

Fig. 2. Speke Glacier seen from point Ρ (see Fig. 5). Photograph taken by the authors on 29 January 1990.

Figure 2

Fig. 5. The terminus positions of Speke Glacier in 1950 (after Menzies, 1951), 1958 (after Whittow and others, 1963) and January 1990. The figure is based on the map of Whittow and others, 1963 p. 594).

Figure 3

Fig. 3. Terminus positions of Speke Glaner observed from survey point 2 (see Fig. 5). Solid line, June 1958; broken line, July 1961 (both after Whittow and others, 1963); dotted line, January 1974 (after Hastenrath, 1984). Marks D (note the person sitting on the stone; the mark itself is hidden behind a plant), Β and C from left are circled. Photograph taken by the authors on 29 January 1990.

Figure 4

Fig. 4. Terminus positions of Speke Glacier as seen from survey point 1 (see Fig. 5). Lines and references are the same as in Figure 3. Mark G is circled. Photograph taken by the authors on 29 January 1990.

Figure 5

Fig. 6. Speke Glacier as seen from Albert Peak on Mount Stanley. The white line indicates the extent of Speke Glacier as reconstructed on the basis of photographs taken in 1967 (Temple, 1968), 1974 (Hastenrath, 1984) and 1977 (Lichtenegger and Lichtenegger, 1978). During this period no marked variations in the extent of the ice could be seen from the photographs. Photograph taken by H. Wagner on 29 January 1990.

Figure 6

Fig. 7. Terminus fluctuations of Speke Glacier between January 1958 and January 1990 based on measurements from mark D (dots) (Temple, 1968; data in this paper) and from assessments of photographs (triangles) (Lichtenegger and Lichtenegger, 1978; Hastenrath, 1984).