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Ice-cores, sediments and civilisation collapse: a cautionary tale from Lake Titicaca

Published online by Cambridge University Press:  10 March 2015

Michael J. Calaway*
Affiliation:
Department of Geological Sciences, Binghamton University (SUNY), Binghamton, NY 13902, USA (Email: mcalaway2@houston.rr.com)

Abstract

The temptation to equate environmental change with archaeologically observed events is always with us, and matching a climatic downturn with civilisation collapse is perhaps more attractive then ever. The archaeologically observed collapse of the Tiwanaku civilisation in the twelfth century AD has been specifically related to a prolonged drought which would have affected the people’s ability to produce food. However, a careful scrutiny of the data from ice cores and lake sediments persuades the author that no such drought can be inferred: the evidence for climatic change is of quite a different scale and order to the archaeological changes and cannot be used as an explanation of social events.

Type
Research
Copyright
Copyright © Antiquity Publications Ltd. 2005

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References

Abbott, M., Binford, M. Brenner, M. & Kelts, K.. 1997. A 3,500 14C yr high-resolution sediment record of lake level changes in Lake Titicaca, Bolivia/Peru. Quaternary Research 47: 169–80.CrossRefGoogle Scholar
Biesboer, D., M. Binford & Kolata, A.. 1999. Nitrogen fixation in soils and canals of rehabilitated raised fields in the Bolivian altiplano. Biotropica 31: 255–67.Google Scholar
Binford, M., Kolata, A. Brenner, M. Janusek, J. Seddon, M. Abbott, M. & Curtis, J.. 1997. Climate variation and the rise and fall of an Andean civilization. Quaternary Research 47: 235–48.CrossRefGoogle Scholar
Calancha, A. 1939. Cronica Moralizada de la Orden de San Agustin del Peru [1638]. La Paz, Bolivia: Imprenta Artistica.Google Scholar
Calaway, M.J. 2001. Environmental factors and prehistoric societal collapse: exploring the agro-ecological collapse of the Tiwanaku civilization and environmental time-scales. MA Thesis. State University of New York at Binghamton.Google Scholar
Carney, H.J., Binford, M. Kolata, A. Marin, R. & Goldman, C.. 1993. Nutrient and sediment retention in Andean raised-field agriculture. Nature 364: 131–3.Google Scholar
Castelnau, F. 1939. El Pueblo de Tihuanacu. [18501851], in Otero, G. (ed.) Tihuanacu: antologia de los principales escritos de los cronistas coloniales, americanistas e historiadores bolivianos, Biblioteca Boliviana 2: 7887. La Paz, Bolivia: Imprenta Aristica.Google Scholar
De Leon, Cieza, De, Pedro. 1969. The Incas of Pedro de Cieza de Leon Von Hagen, V.W. & de Onis, Harriet (ed.) Norman: University of Oklahoma Press.Google Scholar
Clifford, N.J. & Mcclatchey, J.. 1996. Identifying the time-scales of environmental change: the instrumental record, in Driver, T. & Chapman, G. (ed.) Time-scales & environmental change: 88107. London: Routledge.Google Scholar
Driver, T.S. & Chapman, G.P.. 1996. Time, mankind, and the earth, in Driver, T. & Chapman, G. (ed.) Time-scales & environmental change: 124. London: Routledge.Google Scholar
Erickson, C. 1988. An archaeological investigation of raised fields in the Lake Titicaca Basin of Peru. PhD Thesis. University of Illinois.Google Scholar
Erickson, C. 1999. Neo-environmental determinism and agrarian ‘collapse’ in Andean prehistory. Antiquity 73: 634–42.CrossRefGoogle Scholar
Fagan, B. 1999. Floods, famines, and emperors: El Niño and the fate of civilizations. New York: HarperCollins.Google Scholar
Fagan, B. 2003. The long summer: how climate changed civilization. New York: Basic Books.Google Scholar
Francou, B., Sicart, J.-E. Vuille, M. Wagnon, P. & Mendoza, J.. 2003. Tropical climate change recorded by a glacier in the central Andes during the last decades of the twentieth century: Chacaltaya, Bolivia, 16?S. Journal of Geophysical Research D: Atmospheres 108 (5) (16 MAR): ACL 1-1-1-12.CrossRefGoogle Scholar
Grove, J. 1996. The century time-scale, in Driver, T. & Chapman, G. (ed.) Time-scales & environmental change: 3987. London: Routledge.Google Scholar
Hardy, D.R., Vuille, M. Braun, C. Keimig, F. & Bradley, R.S.. 1998. Annual and daily meteorological cycles at high altitude on a tropical mountain. Bulletin of the American Meteorological Society 79: 1899913.Google Scholar
Henderson, K.A., Thompson, L.G. & Lin, P.-N.. 1999. Recording of El Niño in ice core delta 18 oxygen records from Nevado Huascarán, Peru. Journal of Geophysical Research 104 (D24): 3105331065.Google Scholar
Isbell, W.H. 1998. Tiwanaku and its hinterland: archaeology and paleoecology of an Andean civilization (book review). Human Ecology: An Interdisciplinary Journal 26 (3): 519–23.Google Scholar
Keys, D. 2000. Catastrophe: a quest for the origins of the modern world. New York: Ballantine Books.Google Scholar
Kolata, A.L. 1991. The technology and organization of agricultural production in the Tiwanaku state. Latin American Antiquity 2 (2): 99125.Google Scholar
Kolata, A.L. 1993. The Tiwanaku. Oxford: Basil Blackwell.Google Scholar
Kolata, A.L. (ed.) 1996. Tiwanaku and its hinterland: archaeology and paleoecology of an Andean civilization, vol. 1. Washington, D.C.: Smithsonian Institution Press.Google Scholar
Kolata, A.L., Binford, M.W. Brenner, M. Janusek, J.W. & Ortloff, C.. 2000. Environmental thresholds and the empirical reality of state collapse: a response to Erickson (1999). Antiquity 74: 424–6.Google Scholar
Kolata, A. & Ortloff, C.. 1989. Thermal analysis of Tiwanaku raised field systems in the Lake Titicaca basin of Bolivia. Journal of Archaeological Sciences 16: 233–63.Google Scholar
Leyden, B. 1989. Datos Polínicos del Período Holoceno Tardío en el Lago Titicaca, Bolivia: una Posible Inundación en la Pampa Koani, in Kolata, A. (ed.) Arqueología de Lurkurmata, vol. 2: 263–74. La Paz, Bolivia: Producciones Puma Punku.Google Scholar
Ortloff, C. & Kolata, A.. 1993. Climate and collapse: agroecological perspectives on the decline of the Tiwanaku state. Journal of Archaeological Science 20: 195221.CrossRefGoogle Scholar
Posnansky, A. 1945. Tihuanacu: the cradle of American man, vol. 1 and 2. New York: J.J. Augustin.Google Scholar
Redman, C.L. 1999. Human impact on ancient environments. Tucson, AZ: University of Arizona Press.Google Scholar
Rodbell, D.T., Seltzer, G.O. Anderson, D.M. Abbott, M.B. Enfield, D.B. & Newman, J.H.. 1999. An ∼15 000-year record of El Niño-driven alluviation in southwestern Ecuador. Science 283 (5401): 516–20.CrossRefGoogle Scholar
Seltzer, G.O., Baker, P. Cross, S. Dunbar, R. & Fritz, S.. 1998. High-resolution seismic reflection profiles from Lake Titicaca, Peru-Bolivia: evidence for Holocene aridity in the tropical Andes. Geology 26 (2): 167–70.2.3.CO;2>CrossRefGoogle Scholar
Stanley, S.M. 1998. Children of the ice age: how a global catastrophe allowed humans to evolve. New York: W.H. Freeman & Co.Google Scholar
Stevens, W.K. 1999. The change in the weather: people, weather, and the science of climate. New York: Delacorte Press.Google Scholar
Thompson, L.G. 2000. Ice core evidence for climate change in the tropics: implications for the future. Quaternary Science Reviews 19: 1935.Google Scholar
Thompson, L.G., Davis, M.E. Mosley-Thompson, E. & Liu, K.-B.. 1988. Pre-Incan agricultural activity recorded in dust layers in two tropical ice cores. Nature 226 (22/29): 763–5.CrossRefGoogle Scholar
Thompson, L.G., Davis, M.E. Mosley-Thompson, E. Sowers, T.A. Henderson, K.A. Zagorodnov, V.S.-N. Lin, P. Mikhalenko, V.N. Campen, R.K. Bolzan, J.F. Cole-Dai, J. & Francou, B.. 1998. A 25 000-year tropical climate history from Bolivian ice cores. Science 282: 185864.Google Scholar
Thompson, L.G. & Mosley-Thompson, E.. 1992. Tropical ice core paleoclimatic records, Quelccaya ice cap, Peru, AD 470 to 1984, Byrd Polar Research Center Miscellaneous Publication 321. Columbus: Ohio State University Printing Services.Google Scholar
Thompson, L.G., Mosley-Thompson, E. Bolzan, J.F. & Koci, B.R.. 1985. A 1500-year record of tropical precipitation in ice cores from Quelccaya ice cap, Peru. Science 229 (6): 971–3.Google Scholar
Thompson, L.G., Mosley-Thompson, E. Dangaard, W. & Grootes, P.M.. 1986. The little ice age as recorded in the stratigraphy of the tropical Quelccaya ice cap. Science 234 (17): 361–4.Google Scholar
Thompson, L.G., Mosley-Thompson, E. Davis, M.E.-N. Lin, P. Henderson, K.A. Cole-Dai, J. Bolzan, J.F. & Liu, K.-B.. 1995. Late glacial stage and Holocene tropical ice core records from Huascarán, Peru. Science 269: 4650.Google Scholar
Thompson, L.G., Mosley-Thompson, E. Grootes, P.M. Pourchet, M. & Hastenrath, S.. 1984. Tropical glaciers: potential for ice core palaeoclimatic reconstructions. Journal of Geophysical Research 89 (D3): 463846.Google Scholar
Thompson, L.G., Mosley-Thompson, E. & Henderson, K.A.. 2000. Ice-core palaeoclimate records in tropical South America since the last glacial maximum. Journal of Quaternary Science 15 (4): 377–94.Google Scholar
Van Buren, M. 2001. The archaeology of El Niño events and other ‘natural disasters’. Journal of Archaeological Method and Theory 8 (2): 129–49.Google Scholar
Vuille, M. 1999. Atmospheric circulation over the Bolivian altiplano during dry and wet periods and extreme phases of the southern oscillation. International Journal of Climatology 19: 1579600.Google Scholar
Vuille, M., Bradley, R.S. Werner, M. & Keimig, F.. 2003. 20th century climate change in the tropical Andes: observations and model results. Climatic Change 59 (1–2): 7599.Google Scholar
Vuille, M., Hardy, D. Braum, C. Keimig, F. & Bradley, R.. 2001. Climate variability on interseasonal to interannual timescales on the Bolivian altiplano with special emphasis on the Nevado Sajama region. Ecologia en Bolivia 35: 1740.Google Scholar
Williams, P.R. 2002. Rethinking disaster induced collapse in the demise of the Andean highland states: Wari and Tiwanaku. World Archaeology 33 (3): 361–74.Google Scholar