Hostname: page-component-78c5997874-v9fdk Total loading time: 0 Render date: 2024-11-09T06:44:31.842Z Has data issue: false hasContentIssue false

A Late Quaternary Pollen Record from the Transvaal Bushveld, South Africa

Published online by Cambridge University Press:  20 January 2017

Louis Scott*
Affiliation:
Institute for Environmental Sciences, University of the Orange Free State, P.O. Box 339, Bloemfontein 9300, South Africa

Abstract

Pollen spectra from cores of organic spring deposits from the Transvaal provide evidence for the climatic evolution of the province during the last 35,000 yr B.P. or more. The past climatic phases are derived from palynological reconstructions of past vegetation types by comparison of fossil pollen data with modern surface pollen spectra from various localities. Evidence is provided for an early moist, cool phase with relatively mesic bushveld and expanded montane forest in the central Transvaal, followed by a drier period with drier bushveld which probably lasted until approximately 25,000 yr B.P. During the next phase, which at the latest ended about 11,000 yr B.P., the temperatures were probably 5°–6°C cooler than at present. At that time bushveld vegetation in the central Transvaal was replaced by open grassland with macchia elements. Climatic amelioration came and semiarid savanna returned to the plains, at first gradually and then developing into a warm Kalahari thornveld-type vegetation. After 6000 yr B.P. it apparently became slightly wetter and a more broad-leafed bushveld developed. About 4000 yr B.P. it again became cooler and slightly wetter and the bushveld vegetation on the central and northern plains was comparable to present open upland types. After 2000 yr B.P. conditions gradually became warner until about 1000 yr B.P., when the modern climate of the central Transvaal bushveld originated.

Type
Research Article
Copyright
University of Washington

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Acocks, J.P.H. (1953). Veld types of South Africa. Memoirs of the Botanical Survey, S.A. 28, 1192.Google Scholar
Beaumont, P.B. de Villiers, H. Vogel, J.C. (1978). Modern man in sub-Saharan Africa prior to 49000 years B.P.: A review and evaluation with particular reference to Border Cave. South African Journal of Science 74 1 409419.Google Scholar
Burckle, L.H. (1972). Diatom evidence bearing on the Holocene in the South Atlantic. Quaternary Research 2, 323326.Google Scholar
Butzer, K.W. (1973). Spring sediments from the Acheulian sites of Amanzi (Uitenhage District, South Africa). Quaternaria 16, 299319.Google Scholar
Butzer, K.W. Beaumont, P.B. Vogel, J.C. 1978a. Lithostratigraphy of Border Cave, KwaZulu, South Africa: A Middle Stone Age sequence beginning c. 195 000 B.P.. Journal of Archaeological Science 5, 317341.Google Scholar
Butzer, K.W. Fock, G.J. Stuckenrath, R. Zilch, A. 1973a. Palaeohydrology of Late Pleistocene Lake Alexandersfontein, Kimberley, South Africa. Nature (London) 243, 328330.CrossRefGoogle Scholar
Butzer, K.W. Helgren, D.J. Fock, G.J. Stuckenrath, R. 1973b. Alluvial terraces of the lower Vaal River South Africa: A reappraisal and rein vestigation. The Journal of Geology 81, 841.Google Scholar
Butzer, K.W. Stuckenrath, R. Bruzewicz, Helgren, D.M. 1978b. Late Cenozoic paleoclimates of the Gaap escarpment, Kalahari margin, South Africa. Quaternary Research 10, 310339.CrossRefGoogle Scholar
CLIMAP, . 1976. The surface of the ice-age earth. Science 191, 11311137.Google Scholar
Coates Palgrave, K. (1977). Trees of Southern Africa. Struik Publishers. Cape Twon, Johannesburg.Google Scholar
Coetzee, B.J. van der Meulen, F. Zwanziger, S. Gonsalves, P. Weisser, P. (1976). A phytosociological classification of the Nylsvley Nature Reserve. Bothalia 12, 137160.Google Scholar
Coetzee, B.J. Werger, M.J.A. (1975). A westeast vegetation transect through Africa south of the Tropic of Capricorn. Bothalia 11, 539560.Google Scholar
Coetzee, J.A. (1967). Pollen analytical studies in East and southern Africa. Palaeoecology of Africa 3, 1146.Google Scholar
Coetzee, J.A. (1978). Phytogeographical aspects of the montane forests of the chain of mountains on the eastern side of Africa. Geoecological Relations between the Southern Temperate Zone and the Tropical Mountains Troll, C. Lauer, W. Franz Steiner Verlag. Wiesbaden 482494.Google Scholar
Davis, M.B. (1966). Determination of absolute pollen frequency. Ecology 47, 310311.Google Scholar
Faegri, K. Iversen, J. (1964). Textbook of Pollen Analysis. Blackwell. Oxford.Google Scholar
Grunow, J.O. (1967). Objective classification of plant communities: A synecological study in the sourish mixed bushveld of Transvaal. Journal of Ecology 55, 691710.Google Scholar
Hays, J.D. Imbrie, J. Schacleton, N.J. (1976). Variations in the earth's orbit: Pacemaker of the ice ages. Science 194, 11211132.Google Scholar
Heine, K. (1978). Jungquartäre Pluviale und Interpluviale in der Kalahari (Südliches Afrika). Palaeoecology of Africa 10, 3139.Google Scholar
Heusser, C.J. (1974). Vegetation and climate of the southern Chilean lake district during and since the last interglaciation. Quaternary Research 4, 290315.CrossRefGoogle Scholar
Killick, D.J.B. (1963). An account of the plant ecology of the Cathedral Peak area of the Natal Drakensberg. Memoirs of the Botanical Survey S.A. 34, 1178.Google Scholar
Klein, R.G. (1977). The mammalian fauna from the middle and later Stone Age (Upper Pleistocene) levels of Border Cave, Natal Province, South Africa. South African Archaeological Bulletin 32, 1427.CrossRefGoogle Scholar
Klein, R.G. (1980). Environmental and ecological implications of large mammals from Upper Pleistocene and Holocene sites in southern Africa. Annals of the South African Museum 81, 223283.Google Scholar
Lancaster, I.N. (1979). Evidence for a widespread late Pleistocene humid period in the Kalahari. Nature (London) 279, 145146.Google Scholar
Martin, A.R.H. (1968). Pollen analysis of Groenvlei Lake sediments, Knysna (South Africa). Review of Palaeobotany and Palynology 7, 107144.Google Scholar
Macphail, M.K. (1979). Vegetation and climates in southern Tasmania since the last glaciation. Quaternary Research 11, 306341.CrossRefGoogle Scholar
Poynton, R.J. (1971). A silvicultural map of southern Africa. South African Journal of Science 67, 5860.Google Scholar
Schalke, H.J.W.G. (1973). The Upper Quaternary of the Cape flats area (Cape Province, South Africa). Scripta Geologica 15, 157.Google Scholar
Schulze, B.R. (1965). Climate of South Africa, 8. South African Weather Bureau Vol. 28 Government Printer. Pretoria.Google Scholar
Schulze, B.R. (1972). South Africa. World Survey of Climatology: Climates of Africa Griffiths, J.F. Vol. 10 Elsevier. Amsterdam 501586.Google Scholar
Schulze, R.E. McGee, O.S. (1978). Climatic indices and classification in relation to the biogeography of southern Africa. Biogeography and Ecology of Southern Africa Werger, M.J.A. Junk. the Hague 1952.Google Scholar
Scott, L. (1979). Late Quaternary pollen analytical studies in the Transvaal (South Africa). Ph.D. Thesis. University of the Orange Free State. Bloemfonteinunpublished.Google Scholar
Scott, L. 1982a. Late Quaternary fossil pollen grains from the Transvaal, South Africa. Review of Palaeobotany and Palynology 36in press.Google Scholar
Scott, L. 1982b. A 5 000-at the north of the Soutpansberg, South Africayear old pollen sequence from spring deposits in the bushveld Palaeoecology of Africa 14in press.Google Scholar
Scott, L. Vogel, J.C. (1978). Pollen analyses of the thermal spring deposit at Wonderkrater (Transvaal, South Africa). Palaeoecology of Africa 10, 155162.Google Scholar
Shackleton, N.J. Opdyke, N.D. (1973). Oxygen isotope and palaeomagnetic stratigraphy of equatorial pacific core V 28–238: Oxygen isotope temperatures and ice volumes on a 105 Quaternary Researchyear and 106 year scale 3, 3955.Google Scholar
Stockmarr, J. (1971). Tablets with spores used in absolute pollen analyses. Pollen et Spores XIII, 615621.Google Scholar
Talma, A.S. Vogel, J.C. Partridge, T.C. (1974). Isotopic contents of some Transvaal speleothems and their palaeoclimatic significance. South African Journal of Science 80, 135140.Google Scholar
Torrance, J.D. (1972). Malawi, Rhodesia and Zambia. World Survey of Climatology: Climates of Africa Griffiths, J.F. Vol. 10 Elsevier. Amsterdam 409460.Google Scholar
Trewartha, G.T. (1966). The Earth's Problem Climates. Methuen. London.Google Scholar
Troll, C. (1948). Der asymmetrische Afbau der Vegetationszonen und Vegetationstufen auf der Nordund Südhalbkugel. Berichte Geobotanisch Forschungsinstitut 5, 4683.Google Scholar
van der Hammen, T. Maarleveld, G.C. Vogel, J.C. Zagwijn, W.H. (1967). Stratigraphy, climatic succession and radiocarbon dating of the last glacial in the Netherlands. Geologie en Mijnbouw 46, 7995.Google Scholar
van der Meulen, F. (1979). Plant sociology of the western Transvaal bushveld, South Africa. Dissertationes Botanicae 49, 1192.Google Scholar
van der Schijff, H.P. Schoonraad, E. (1971). The flora of the Mariepskop complex. Bothalia 10, 461500.Google Scholar
van Zinderen Bakker, E.M. Jr.. 1973. Ecological investigations of forest communities in the eastern Orange Free State and the adjacent Natal Drakensberg. Vegetatio 29, 299334.Google Scholar
van Zinderen Bakker, E.M. Sr.. 1957. A pollen analytical investigation of the Florisbad deposits (South Africa). Proceedings, Third Pan-African Congress, Prehistory Clark, J.D. Livingstone. London 5667(1955).Google Scholar
van Zinderen Bakker, E.M. Sr.. 1969. Cold spell of world-wide nature at about 5500-4700 B.P.. Palaeoecology of Africa 4, 8.Google Scholar
van Zinderen Bakker, E.M. Sr.. 1976a. The evolution of late Quaternary palaeoclimates of southern Africa. Palaeoecology of Africa 9, 160201.Google Scholar
van Zinderen Bakker, E.M. Sr.. 1976b. Late Quaternary environmental changes in southern Africa. Annals of the South African Museum 71, 141152.Google Scholar
van Zinderen Bakker, E.M. Sr.. 1978. Quaternary vegetation changes in southern Africa. Biogeography and Ecology of Southern Africa Werger, M.J.A. Junk. The Hauge 131143.CrossRefGoogle Scholar
van Zinderen Bakker, E.M. Sr.. 1979. Comparison of late Quaternary climatic evolutions in the Sahara and the Namib-Kalahari region. Palaeoecology of Africa 12, 381394.Google Scholar
Walter, H. Lieth, H. (1960). Klimmadiagramm-Weltatlas. Gustav Fischer Verlag. Jena.Google Scholar
Webster, P.J. Streten, N.A. (1978). Late Quaternary ice age climates of tropical Australia: Interpretations and reconstructions. Quaternary Research 10, 279309.Google Scholar
Werger, M.J.A. (1978). Biogeographical division of southern Africa. Biogeography and Ecology of Southern Africa Werger, M.J.A. Junk. The Hague 145170.Google Scholar
Werger, M.J.A. Coetzee, B.J. (1978). The Sudano-Zambezian region. Biogeography and Ecology of Southern Africa Werger, M.J.A. Junk. The Hague 301462.Google Scholar
White, F. (1978). The Afromontane region. Biogeography and Ecology of Southern Africa Werger, M.J.A. Junk. The Hague 463514.Google Scholar