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Late Quaternary Rock Glaciers, Mount Kenya, Kenya

Published online by Cambridge University Press:  20 January 2017

W. C. Mahaney
W. C. Mahaney*
Affiliation:
Department of Geography, York University, Toronto, Ontario M3J 2R7,, Canada
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Abstract

Rock glaciers in Teleki Valley on Mount Kenya exist above 4 000 m below steep valley walls where they are supplied with debris from avalanche couloirs. These valley-side rock glaciers consist of three or four lobes of rubble bounded by transverse furrows resulting from differential movement. No ice cores were observed in these rubble sheets, but “drunken forest” stands of Senecio keniodendron indicate the probable presence of interstitial ice resulting either from the metamorphism of snow buried under rockfall and slide-rock debris, or from freezing of water beneath the rock mantle. A geological survey of Mount Kenya in 1976 revealed that rock glaciers are anomalous in the Mount Kenya Afroalpine zone above 3 300 m. Analysis of weathering rinds indicates that several rock-glacier lobes were built up over a short interval of time at or near the end of the last glacial maximum (Würm). Oversteepened fronts on the westernmost lobes may have resulted from re-activation coinciding with the advance of glaciers during late Holocene time (<1 000 B.P.). Soils mantle 20% of the rock-glacier surface and have morphological characteristics comparable with soils forming on moraines of late Würm age in upper Teleki, Hausberg, and Mackinder Valleys.

Résumé

Résumé

Dans la Teleki Valley du Mount Kenya des glaciers rocheux existent au dessus de 4 000 m sous des flancs de vallées très abrupts où ils sont nourris en sédiments par des couloirs d’avalanches. Ces glaciers rocheux de vallées latérales consistent en trois ou quatre lobes de blocailles limitées par des failles transversales résultant de mouvements différentiels. On n’a pas observé de coeurs de glace dans ces couvertures de blocailles, mais des stations de “forêt ivre” de Senecio keniodendron indiquent la présence probable de glace interstitielle résultant soit de la transformation de la neige enfouie sous les chutes de blocs et les glissements de terrains, soit du regel de l’eau sous le manteau de rochers. Une reconnaissance géologique du Mount Kenya en 1976 a révélé que les glaciers rocheux sont anormaux dans la zone Afroalpine du Mount Kenya au dessus de 3 300 m. L’analyse des datations d’écorces indiquent que plusieurs lobes de glaciers rocheux ont été construits en un court intervalle de temps au moment ou près de la fin du dernier maximum glaciaire (Würm). Les fronts surabrupts des lobes occidentaux peuvent résulter de la ré-activation coïncidant avec l'avance des glaciers lors de la dernière période holocéne (moins de 1 000 ans avant le présent). Des sols recouvrent 20% de la surface des glaciers rocheux et ont des caractéristiques morphologiques comparables aux sols en formation sur les moraines de la fin du Würm dans les hautes vallées du Teleki, de Hausberg et de Mackinder.

Zusammenfassung

Zusammenfassung

Im Teleki Valley am Mt Kenya gibt es über 4 000 m Höhe unter steilen Talwänden Blockgletscher, die aus Lawinenrinnen mit Schutt versorgt werden. Diese Blockgletscher am Talrand bestehen aus drei oder vier Schuttloben, die von Querfurchen, erzeugt durch differentielle Bewegung, begrenzt sind. Eiskerne konnten in diesen Schuttdecken nicht gefunden werden, doch deuten Steilen von “drunken forest” mit Senecio keniodendron auf das Vorhandensein von Zwischeneisschichten hin, die entweder aus der Umwandlung von Schnee, der unter Felsstürzen und Hangschutt begraben wurde, oder durch Gefrieren von Wasser unter dem Schuttmantel entstanden sind. Eine geologische Erkundung des Mt Kenya im Jahre 1976 ergab, dass Blockgletscher in der afroalpinen Zone des Mt Kenya über 3 300 m ungewühnlich sind. Die Analyse von Verwitterungsrinden weist darauf hin, dass Blockgletscherloben in einem kurzen Zeitintervall während oder nahe am Ende des letzten Gletscher-hochstandes (Würm) entstanden. Übersteilte Fronten der westlichen Loben können sich bei einer Reaktivierung gebildet haben, die mit dem Gletschervorstoss im späten Holozän (weniger als 1 000 Jahre vor der Gegenwart) zusammenfiel. Bodenbildungen überdecken 20% der Oberfläche der Blockgletscher; morphologisch sind sie mit Böden vergleichbar, die sich auf Moränen der späten Würm-Zeit im oberen Teleki, im Hausberg, und im Mackinder Valleys gebildet haben.

Type
Short Notes
Information
Journal of Glaciology , Volume 25 , Issue 93 , 1980 , pp. 492 - 497
Copyright
Copyright © International Glaciological Society 1980

Introduction

Investigation of three rock glaciers on Mount Kenya developed out of a study of Quaternary strati-graphy and soil morphogenesis. Rock glaciers of the valley-side type (Reference Outcalt and BenedictOutcalt and Benedict, 1965) are found in Teleki Valley (Naro Mom River) above 4000 m on Mount Kenya (Fig. 1). Avalanche couloirs deliver trachyte-tuff agglomerate and porphyritic phonolite debris across 30° talus slopes into the three rock-glacier systems. In this paper the origin and age of the rock glaciers are discussed.

Fig. 1. Map of Mount Kenya showing Naro Mora drainage basin.

Field Area

Mount Kenya is a prominent strato-volcano of late Pliocene/early Pleistocene age, located approxi-mately 200 km north of Nairobi, and rising to 5 185 m above the high plateau of Kenya (Fig. 1 (Reference BakerBaker, 1967). Twelve glaciers are found above 4600 m; prominent moraines, outwash trains, alluvial fans, talus cones, and rock glaciers of late Pleistocene/early Holocene age mantle the flanks of the mountain.

Vegetation in the vicinity of the rock glaciers has been described by Reference HedbergHedberg (1964) as belonging to the Upper Alpine group consisting of giant groundsel (Senecio keniodendron), Helichrysum, carex sedge and Agrostis grass, Carduus platyphyllus and Lobelia telekii.

Climatic data for Teleki Valley are incomplete but Reference HedbergHedberg (1964) estimated the mean monthly temperature for August to be 3.1–6°C. Generalized isohyets for 1961 (Reference Coetzee and BalkemaCoetzee, 1967) approximate precipitation to be 108 cm. The wettest slopes are on the south-east flank of the mountain where precipitation reaches 375 cm.

Teleki Valley Rock Glaciers

Lobate-shaped rock glaciers in Teleki Valley consist of poorly sorted and angular debris, principally composed of porphyritic phonolite, agglomerate, and trachytic porphyry derived from nearby bedrock and moraine sources.

No interstitial ice was observed in the three rock-glacier systems but minimum temperatures taken at the base of a 78 cm open soil pit (site TV1, Fig. 2) averaged −4.1°C (n = 5, in August 1976). The lack of interstitial ice is more the rule than the exception according to numerous workers (Reference WhiteWhite, 1976). These three systems have numerous concave depressions behind the outer lobe, a number of lateral, and a few longitudinal furrows and “drunken stands” of S. keniodendron and L. telekii (Fig. 3), suggesting that previous ice had melted out.

At least three lobes that are generally wider than they are long have developed below avalanche talus on the north side of the valley. The thicknesses of the rock glaciers are estimated at 100–150 m, and two of the outermost lobes appear to be re-activated (Fig. 2). However, the lobes on all three systems have c. 80% lichen cover (e.g. Rhizocarpon geographicum, Lecanora spp.?, Umbilicaria haumania, Umbilicaria africana and Usnea), suggesting that movement is exceedingly slow. Isolated boulders and large blocks were found in front of the two re-activated fronts (Fig. 2).

Fig. 2. Map showing distribution of rock glaciers in Teleki Valley at approximately 4 100 m. Late Pleistocene/early Holocene soil profile (TVI) is on the third lobe of the middle system. Soils mantle approximately 20% of surface; remaining 80% is an open network of boulders.

Fig. 3. Talus with Lobelia telekii and Senecio keniodendron sparsely distributed on stones feeding into the middle rock-glacier system.

Weathering criteria

The degree of weathering increases from lobe IV to lobe I as shown in Table I.

The data indicate that the several lobes have similar ages and correlate closely with late glacial moraines described by Reference Mahaney and MahaneyMahaney (in press).

Table I. Weathering Criteria Used to Differentiate Rock-Glacier Lobes

Soil Development

A discontinuous distribution of fine sediment supports a moderately developed Inceptisol as well as numerous grasses and sedges. A thin 1–3 cm mat of partly decayed black organic material (10YR 1/1, 2/1 m) overlies a pedon (TV1 soil profile) with the following horizonation:

Particle-size de terminations indicate that two parent materials are present (e.g. rock-glacier debris and loess). The data are shown in Table II.

The upward-fining sequence where silt is higher in the solum and lower in the sub-soil compares closely with soils on nearby end moraines of late Würm age (Reference Mahaney and BalkemaMahaney, 1979) in Teleki, Mackinder, and Liki North Valleys, and with late-glacial soils in the Rocky Mountains (Reference Mahaney and MahaneyMahaney, 1974). The higher clay and silt quantities in the solum of this soil further substantiate the observations of Reference ZeunerZeuner (1949), who described aeolian materials in soils on the mountain.

No clay minerals were detected in the < 2 μm grade-size material. However, rock-forming minerals in the fine clay-grade size include plagioclase and quartz. Feldspars exist in trace quantities throughout the soil, while quartz ranges from moderately abundant (>50% on diffractograms) in the A11, A12, and IICox horizons to traces in the B2ir horizon. The absence of clay minerals is noteworthy, especially since they occur in other nearby late-glacial soil systems (Mahaney, in press).

Table II. Particle-Size Distribution* for the Soil Horizons in Profile Tv1

The analysis by X-ray diffractometry of primary minerals in the silt-sized fractions (63–4 μm) indicates that quartz is nil in the solum, increasing to small amounts (30–50% based on peak height above background radiation) in the C horizon. Feldspar is found in trace amounts in the upper solum and increases to small and moderate amounts in the B and G horizons. The data correlate closely with mineral assemblages found in nearby soils forming on late glacial moraine systems and suggest that common rock-forming minerals weather quickly in soils above the timber line.

Conclusion

Three massive valley-side rock glaciers are found in Teleki Valley just above the 4000 m contour. Numerous criteria including transverse furrows, steep re-activated fronts, and “drunken stands” of giant groundsel and lobelia attest to differential movement, but no interstitial ice cores were observed in the field. Rainfall and temperature regimes are marginally sufficient to support the growth of ice in the rock lobes. Soil and weathering criteria suggest a late-glacial age for the rock glaciers, while re-activation as indicated by steep fronts may have coincided with the advent of glacial advance in the late Holocene (< 1000 years B.P.).

Acknowledgements

I thank Barry D. Fahey (Guelph University) and Sidney E. White (Ohio State University) for critical reviews of this paper. W. Ahlborn, B. Blatherwick, R. Blatherwick, G. Carr, L. Gowland, D, Halvorson, L, M. Mahaney, and students in my mountain geomorphology course (1976) assisted with the field work. P. M. Snyder, F. W, Woodley, and the Mount Kenya Ranger Force provided invaluable assistance and support, as did W. and D. Gurry of Naro Moru River Lodge. G. Berssenbrugge, L. Gowland, and M. Bardecki assisted with the laboratory analyses. Research was supported by grants from the National Geographic Society and York University.

References

Baker, B. H. 1967. Geology of the Mount Kenya area. Kenya. Geological Survey. Report No. 79.Google Scholar
Birkeland, P. W. 1974. Pedology, weathering, and geomorphological research. New York, -Oxford University Press.Google Scholar
Coetzee, J. A. 1967. Pollen analytical studies in East and southern Africa. Cape Town, Balkema, A. A. (Palaeoecology of Africa and of the Surrounding Islands and Antarctica, Vol. 3.)Google Scholar
Hedberg, O. 1964. Features of Afroalpine plant ecology. Acta Phytogeographica Suecica, 49.Google Scholar
Mahaney, W. C. Soil stratigraphy and genesis ofneoglacial deposits in the Arapaho and Henderson cirques, central Colorado Front Range. (In Mahaney, W. C., ed. Quaternary environments: proceedings of a symposium. First York University Symposium on Quaternary Research, 1974. Toronto, York University, Atkinson College, p. 197240.Google Scholar
Mahaney, W. C. 1979. Reconnaissance Quaternary stratigraphy of Mt. Kenya. Cape Town, Balkema, A. A. (Palaeoecology of Africa and of the Surrounding Islands and Antarctica, Vol. 10.)Google Scholar
Outcalt, S. I. and Benedict, J. B. 1965. Photo-interprelation of two types of rock glacier in the Colorado Front Range, U.S.A. Journal of Glaciology, Vol. 5, No. 42, p. 84956.CrossRefGoogle Scholar
U.S. Bureau of Plant Industry, Soils and Agricultural Engineering. Division of Soil Survey. 1951. Soil survey manual, by Soil Survey staff. U.S. Dept. of Agriculture. Agriculture Handbook, 18.Google Scholar
U.S. Soil Conservation Service. 1960. Soil classification: a comprehensive system, [prepared by] Soil Survtry staff. 7th approximation. Washington, D.C., U.S. Government Printing Office.Google Scholar
White, S. E. 1976. Rock glaciers and block fields, review and new data. Quaternary Research, Vol. 6, No. 1, p. 7797.CrossRefGoogle Scholar
Zeuner, F. E. 1949. Frost soils on Mount Kenya and the relation of frost soils to aeolian deposits. Journal of Soil Science, Vol. 1, No. 1, p. 2030.CrossRefGoogle Scholar
Figure 0

Fig. 1. Map of Mount Kenya showing Naro Mora drainage basin.

Figure 1

Fig. 2. Map showing distribution of rock glaciers in Teleki Valley at approximately 4 100 m. Late Pleistocene/early Holocene soil profile (TVI) is on the third lobe of the middle system. Soils mantle approximately 20% of surface; remaining 80% is an open network of boulders.

Figure 2

Fig. 3. Talus with Lobelia telekii and Senecio keniodendron sparsely distributed on stones feeding into the middle rock-glacier system.

Figure 3

Table I. Weathering Criteria Used to Differentiate Rock-Glacier Lobes

Figure 4

Table II. Particle-Size Distribution* for the Soil Horizons in Profile Tv1