Book contents
- Only in Africa
- Only in Africa
- Copyright page
- Dedication
- Contents
- Foreword
- Preface
- Abbreviations
- Part I The Physical Cradle: Land Forms, Geology, Climate, Hydrology and Soils
- Part II The Savanna Garden: Grassy Vegetation and Plant Dynamics
- Part III The Big Mammal Menagerie: Herbivores, Carnivores and Their Ecosystem Impacts
- Part IV Evolutionary Transitions: From Primate Ancestors to Modern Humans
- Appendix Scientific Names of Extant Animal and Plant Species Mentioned in the Book Chapters (Ecologically Conservative with Regard to Species Recognition)
- Index
- References
Part I - The Physical Cradle: Land Forms, Geology, Climate, Hydrology and Soils
Published online by Cambridge University Press: 09 September 2021
Book contents
- Only in Africa
- Only in Africa
- Copyright page
- Dedication
- Contents
- Foreword
- Preface
- Abbreviations
- Part I The Physical Cradle: Land Forms, Geology, Climate, Hydrology and Soils
- Part II The Savanna Garden: Grassy Vegetation and Plant Dynamics
- Part III The Big Mammal Menagerie: Herbivores, Carnivores and Their Ecosystem Impacts
- Part IV Evolutionary Transitions: From Primate Ancestors to Modern Humans
- Appendix Scientific Names of Extant Animal and Plant Species Mentioned in the Book Chapters (Ecologically Conservative with Regard to Species Recognition)
- Index
- References
Summary
Africa emerged from the middle of the supercontinent called Gondwana, splitting from the land masses that became South America, Australia, India and Antarctica (Figure I.1). The rupture was initiated by massive outpourings of flood basalts, which commenced 183 million years ago (Ma) during the early Jurassic period in what is now southern Mozambique. The volcanic overlay spread inland from there at least as far as south-western Zambia. By 160 Ma, a widening trough separated Africa from eastern Antarctica and Madagascar, filled by the proto-Indian Ocean. In the west, the separation of South America from Africa began with lava eruptions in what is now Namibia, initiated around 123 Ma, and the South Atlantic Ocean began opening. Unencumbered by adjoining land masses, Africa drifted slowly northward, and rotated a little anticlockwise. The location of the equator shifted from the southern Sahara region towards its current middle position, with similar portions of the continent to its north and south. Once the continents eventually halted their drift, South America lay almost 3000 km from the nearest point of Africa, while Australia ended up almost 10,000 km distant on the other side of the Indian Ocean. The Tethys Sea separated Africa from Europe.
Information
- Type
- Chapter
- Information
- Only in AfricaThe Ecology of Human Evolution, pp. 1 - 62Publisher: Cambridge University PressPrint publication year: 2021
References
McCarthy, T; Rubidge, B. (2005) The Story of Earth & Life. A Southern African Perspective on a 4.6-Billion-Year Journey. Struik Nature, Cape Town.Google Scholar
Partridge, TC. (2010) Tectonics and geomorphology of Africa during the Phanerozoic. In Werdelin, L; Sanders, WJ (eds) Cenozoic Mammals of Africa. University of California Press, Berkeley, pp. 3–17.CrossRefGoogle Scholar
Suggested Further Reading
Burke, K; Gunnell, Y. (2008) The African erosion surface: a continental-scale synthesis of geomorphology, tectonics, and environmental change over the past 180 million years. Geological Society of America Memoirs 201:1–66.Google Scholar
Macgregor, D. (2015) History of the development of the East African Rift System: a series of interpreted maps through time. Journal of African Earth Sciences 101:232–252.CrossRefGoogle Scholar
References
Partridge, TC. (2010) Tectonics and geomorphology of Africa during the Phanerozoic. In Werdelin, L; Sanders, WJ (eds) Cenozoic Mammals of Africa. University of California Press, Berkeley, pp. 3–17.Google Scholar
Burke, K; Gunnell, Y. (2008) The African erosion surface: a continental-scale synthesis of geomorphology, tectonics, and environmental change over the past 180 million years. Geological Society of America Memoirs 201:1–66.Google Scholar
Mathu, EM; Davies, TC. (1996) Geology and the environment in Kenya. Journal of African Earth Sciences 23:511–539.Google Scholar
Suggested Further Reading
Burke, K; Gunnell, Y. (2008) The African erosion surface: a continental-scale synthesis of geomorphology, tectonics, and environmental change over the past 180 million years. Geological Society of America Memoirs 201:1–66.Google Scholar
Feakins, SJ; deMenocal, PB. (2010) Global and African regional climate during the Cenozoic. In Werdelin, L; Sanders, WJ (eds) Cenozoic Mammals of Africa. University of California Press, Berkeley, pp. 45–55.Google Scholar
Levin, NE. (2015) Environment and climate of early human evolution. Annual Review of Earth and Planetary Sciences 43:405–429.Google Scholar
Sepulchre, P, et al. (2006) Tectonic uplift and Eastern Africa aridification. Science 313:1419–1423.Google Scholar
References
Malherbe, J, et al. (2020) Recent droughts in the Kruger National Park as reflected in the extreme climate index. African Journal of Range & Forage Science 37:1–17.Google Scholar
Walling, DE. (1996) Hydrology and rivers. In Adams, WM, et al. (eds) The Physical Geography of Africa. Oxford University Press, Oxford, pp. 103–121.Google Scholar
Partridge, TC. (1997) Late Neogene uplift in eastern and southern Africa and its paleoclimatic implications. In Ruddiman, WF (ed.) Tectonic Uplift and Climate Change. Springer, New York, pp. 63–86.Google Scholar
Zachos, J, et al. (2001) Trends, rhythms, and aberrations in global climate 65 Ma to present. Science 292:686–693.Google Scholar
Burke, K; Gunnell, Y. (2008) The African erosion surface: a continental-scale synthesis of geomorphology, tectonics, and environmental change over the past 180 million years. Geological Society of America Memoirs 201:1–66.Google Scholar
Denton, GH. (1999) Cenozoic climate change. In Bromage, TG; Schrenk, F (eds) African Biogeography, Climate Change, and Human Evolution. Oxford University Press, Oxford, pp. 94–114.CrossRefGoogle Scholar
Feakins, SJ; deMenocal, PB. (2010) Global and African regional climate during the Cenozoic. In Werdelin, L; Sanders, WJ (eds) Cenozoic Mammals of Africa. University of California Press, Berkeley, pp. 45–55.Google Scholar
Sepulchre, P, et al. (2006) Tectonic uplift and Eastern Africa aridification. Science 313:1419–1423.CrossRefGoogle ScholarPubMed
Maslin, MA; Christensen, B. (2007) Tectonics, orbital forcing, global climate change, and human evolution in Africa: introduction to the African paleoclimate special volume. Journal of Human Evolution 53:443–464.CrossRefGoogle Scholar
Singarayer, JS; Burrough, SL. (2015) Interhemispheric dynamics of the African rainbelt during the late Quaternary. Quaternary Science Reviews 124:48–67.CrossRefGoogle Scholar
Scholz, CA, et al. (2007) East African megadroughts between 135 and 75 thousand years ago and bearing on early-modern human origins. Proceedings of the National Academy of Sciences of the United States of America 104:16416–16421.CrossRefGoogle ScholarPubMed
Tierney, JE, et al. (2008) Northern hemisphere controls on tropical southeast African climate during the past 60,000 years. Science 322:252–255.Google Scholar
Burnett, AP, et al. (2011) Tropical East African climate change and its relation to global climate: a record from Lake Tanganyika, Tropical East Africa, over the past 90+ kyr. Palaeogeography Palaeoclimatology Palaeoecology 303:155–167.CrossRefGoogle Scholar
Blome, MW, et al. (2012) The environmental context for the origins of modern human diversity: a synthesis of regional variability in African climate 150,000–30,000 years ago. Journal of Human Evolution 62:563–592.CrossRefGoogle ScholarPubMed
Magill, CR, et al. (2013) Ecosystem variability and early human habitats in eastern Africa. Proceedings of the National Academy of Sciences of the United States of America 110:1167–1174.Google Scholar
Trauth, MH, et al. (2007) High- and low-latitude forcing of Plio–Pleistocene East African climate and human evolution. Journal of Human Evolution 53:475–486.Google Scholar
Tyson, PD, et al. (2001) Late Quaternary environmental change in southern Africa. South African Journal of Science 97:139–150.Google Scholar
Engelbrecht, FA, et al. (2019) Downscaling last glacial maximum climate over southern Africa. Quaternary Science Reviews 226:105879.Google Scholar
Shaw, PA; Thomas, DSG. (1996) The quaternary palaeoenvironmental history of the Kalahari, Southern Africa. Journal of Arid Environments 32:9–22.CrossRefGoogle Scholar
Cordova, CE, et al. (2017) Late Pleistocene–Holocene vegetation and climate change in the middle Kalahari, Lake Ngami, Botswana. Quaternary Science Reviews 171:199–215.Google Scholar
Simon, MH, et al. (2015) Eastern South African hydroclimate over the past 270,000 years. Scientific Reports 5.Google Scholar
Schefuss, E, et al. (2011) Forcing of wet phases in southeast Africa over the past 17,000 years. Nature 480:509–512.CrossRefGoogle Scholar
Zhang, ZS, et al. (2014) Aridification of the Sahara desert caused by Tethys Sea shrinkage during the Late Miocene. Nature 513:401–404.Google Scholar
Suggested Further Reading
Fynn, RWS, et al. (2015) African wetlands and their seasonal use by wild and domestic herbivores. Wetlands Ecology and Management 23:559–581.Google Scholar
Walling, DE. (1996). Hydrology and rivers. In Adams, WM, et al. (eds) The Physical Geography of Africa. Oxford University Press, Oxford, pp. 103–121.Google Scholar
References
McCarthy, T; Rubidge, BS. (2005) The Story of Earth and Life. A Southern African Perspective on a 4.6-Billion-Year Journey. Struik, Cape Town.Google Scholar
Moore, A, et al. (2017) A geomorphic and geological framework for the interpretation of species diversity and endemism in the Manica Highlands. Kirkia 19:54–69.Google Scholar
Burrough, SL, et al. (2009) Mega-lake in the Kalahari: a Late Pleistocene record of the Palaeolake Makgadikgadi system. Quaternary Science Reviews 28:1392–1411.Google Scholar
Beverly, EJ, et al. (2020) Rapid Pleistocene desiccation and the future of Africa’s Lake Victoria. Earth and Planetary Science Letters 530:115883.CrossRefGoogle Scholar
Lyons, RP, et al. (2015) Continuous 1.3-million-year record of East African hydroclimate, and implications for patterns of evolution and biodiversity. Proceedings of the National Academy of Sciences of the United States of America 112:15568–15573.Google Scholar
Mendelsohn, JM, et al. (2010) Okavango Delta: Floods of Life. IUCN Gland (Suiza) Harry Oppenheimer Okavango Research Centre, Maun (Botswana).Google Scholar
Shaw, PA; Thomas, DSG. (1996) The quaternary palaeoenvironmental history of the Kalahari, Southern Africa. Journal of Arid Environments 32:9–22.Google Scholar
Naidoo, R, et al. (2020) Mapping and assessing the impact of small‐scale ephemeral water sources on wildlife in an African seasonal savannah. Ecological Applications 30:e02203.CrossRefGoogle Scholar
Parris, R. (1984) Pans, rivers and artificial waterholes in the protected areas of the south-western Kalahari. Koedoe: African Protected Area Conservation and Science 27:63–82.Google Scholar
Lupien, RL, et al. (2018) A leaf wax biomarker record of early Pleistocene hydroclimate from West Turkana, Kenya. Quaternary Science Reviews 186:225–235.Google Scholar
Potts, R, et al. (2018) Environmental dynamics during the onset of the Middle Stone Age in eastern Africa. Science 360:86–90.CrossRefGoogle ScholarPubMed
Scholz, CA, et al. (2007) East African megadroughts between 135 and 75 thousand years ago and bearing on early-modern human origins. Proceedings of the National Academy of Sciences of the United States of America 104:16416–16421.Google Scholar
Blome, MW, et al. (2012) The environmental context for the origins of modern human diversity: a synthesis of regional variability in African climate 150,000–30,000 years ago. Journal of Human Evolution 62:563–592.Google Scholar
Burnett, AP, et al. (2011) Tropical East African climate change and its relation to global climate: a record from Lake Tanganyika, Tropical East Africa, over the past 90+ kyr. Palaeogeography Palaeoclimatology Palaeoecology 303:155–167.Google Scholar
Walling, DE (1996). Hydrology and rivers. In Adams, WM et al. (eds) The Physical Geography of Africa. Oxford University Press, Oxford, pp. 103–121.Google Scholar
Suggested Further Reading
McCarthy, T; Rubidge, BS. (2005) The Story of Earth and Life. A Southern African Perspective on a 4.6-Billion-Year Journey. Struik, Cape Town.Google Scholar
References
Scoon, RN, et al. (2018) Geology of National Parks of Central/Southern Kenya and Northern Tanzania. Springer, Cham.CrossRefGoogle Scholar
Macgregor, D. (2015) History of the development of the East African Rift System: a series of interpreted maps through time. Journal of African Earth Sciences 101:232–252.Google Scholar
Partridge, TC. (2010) Tectonics and geomorphology of Africa during the Phanerozoic. In Werdelin, L; Sanders, WJ (eds) Cenozoic Mammals of Africa. University of California Press, Berkeley, pp. 3–17.Google Scholar
Asrat, A. (2016) The Ethiopian highlands. In Viljoen, R (ed.) Africa’s Top Geological Sites. Struik, Cape Town, pp. 197–205.Google Scholar
Asrat, A. (2016) The Danakil depression of Ethiopia. In Viljoen, R (ed.) Africa’s Top Geological Sites. Struik, Cape Town, pp. 189–196.Google Scholar
Haddon, IG. (2004) The Sub-Kalahari Geology and Tectonic Evolution of The Kalahari Basin, Southern Africa. University of the Witwatersand, Johannesburg.Google Scholar
Suggested Further Reading
Jones, A, et al. (2013) Soil Atlas of Africa. European Commission, Publications of the European Union, Luxembourg.Google Scholar
References
Areola, O. (1996) Soils. In Adams, WM, et al. (eds) The Physical Geography of Africa. Oxford University Press, Oxford, pp. 134–147.Google Scholar
Huston, MA. (2012) Precipitation, soils, NPP, and biodiversity: resurrection of Albrecht’s curve. Ecological Monographs 82:277–296.Google Scholar
Crowther, TW, et al. (2019) The global soil community and its influence on biogeochemistry. Science 365:772.Google Scholar
Pellegrini, AFA. (2016) Nutrient limitation in tropical savannas across multiple scales and mechanisms. Ecology 97:313–324.Google Scholar
Jones, A, et al. (2013) Soil Atlas of Africa. European Commission, Publications of the European Union: Luxembourg.Google Scholar
Runge, J. (2016) Soils and duricrusts. In Knight, J; Grab, SW (eds) Quaternary Environmental Change in Southern Africa. Cambridge University Press, Cambridge, pp. 234–249.Google Scholar
Anderson, GD; Talbot, LM. (1965) Soil factors affecting the distribution of the grassland types and their utilization by wild animals on the Serengeti Plains, Tanganyika. The Journal of Ecology 53:33–56.Google Scholar
de Wit, HA. (1978) Soils and grassland types of the Serengeti Plains (Tanzania). PhD thesis, Wageningen University, Wageningen.Google Scholar
Jager, T. (1982) Soils of the Serengeti woodlands, Tanzania. PhD thesis, Wageningen University, Wageningen.Google Scholar
Anderson, TM. (2008) Plant compositional change over time increases with rainfall in Serengeti grasslands. Oikos 117:675–682.Google Scholar
Grant, CC; Scholes, MC. (2006) The importance of nutrient hot-spots in the conservation and management of large wild mammalian herbivores in semi-arid savannas. Biological Conservation 130:426–437.Google Scholar
Goudie, AS. (1988) The geomorphological role of earthworms and termites in the tropics. In Viles, H (ed.) Biogeomorphology. Blackwell, Oxford, pp. 43–82.Google Scholar
Jouquet, P, et al. (2011) Influence of termites on ecosystem functioning. Ecosystem services provided by termites. European Journal of Soil Biology 47:215–222.Google Scholar
Augustine, DJ. (2003) Long-term, livestock-mediated redistribution of nitrogen and phosphorus in an East African savanna. Journal of Applied Ecology 40:137–149.CrossRefGoogle Scholar
Muchiru, AN, et al. (2009) The impact of abandoned pastoral settlements on plant and nutrient succession in an African savanna ecosystem. Journal of Arid Environments 73:322–331.Google Scholar
van der Waal, C, et al. (2011) Large herbivores may alter vegetation structure of semi-arid savannas through soil nutrient mediation. Oecologia 165:1095–1107.CrossRefGoogle ScholarPubMed
Blackmore, AC, et al. (1990) The origin and extent of nutrient-enriched patches within a nutrient-poor savanna in South Africa. Journal of Biogeography 17:463–470.Google Scholar
Denbow, JR. (1979) Cenchrus ciliaris: an ecological indicator of Iron Age middens using aerial photography in eastern Botswana. South African Journal of Science 75:405–408.Google Scholar
Accessibility standard: Unknown
Why this information is here
This section outlines the accessibility features of this content - including support for screen readers, full keyboard navigation and high-contrast display options. This may not be relevant for you.Accessibility Information
Accessibility compliance for the HTML of this chapter is currently unknown
and may be updated in the future.