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The Stratigraphy and Fire History of the Kutai Peatlands, Kalimantan, Indonesia

Published online by Cambridge University Press:  20 January 2017

Geoffrey Hope ,
Unna Chokkalingam  and
Syaiful Anwar
Geoffrey Hope
Affiliation:
Archaeology and Natural History, RSPAS, Australian National University, Canberra 0200, Australia
Unna Chokkalingam
Affiliation:
Center for International Forestry Research, Bogor, Indonesia
Syaiful Anwar
Affiliation:
Department of Soil Science, Bogor Agricultural University, Indonesia
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Abstract

The equatorial peatlands of the Kutai lowland of eastern Kalimantan are generally 4–10 m in thickness but some sections exceed 16 m in depth. The deposition of peat commenced about 8000 yrs ago after shallow flooding of the basin by the Mahakam River. The earliest vegetation is a Pandanus swamp which grades upwards to swamp forest dominated by dipterocarps. The peatland has expanded laterally and rivers have maintained narrow levee-channel tracks through the swamp, which has grown vertically in balance with river accretion. Historical fires are associated with extreme El Niño years of drought, but human agency is important. The fires of 1982–1983 and 1997–1998 burnt up to 85% of the vegetation on the peatland. Although charcoal analyses show that fire has occurred throughout the history of the peatland, it is rare in forests remote from rivers until the last 3000 years and only common within the last millennium. Fires are earlier and more frequent in sites accessible from waterways, and floodplains have been widely burnt down to water table or below, forming extensive lakes.

Keywords

Tropical peatlandFire historyCharcoal analysisPalaeolimnology
Type
Special issue articles
Information
Quaternary Research , Volume 64 , Issue 3 , November 2005 , pp. 407 - 417
Copyright
University of Washington

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References

Anderson, J.A.R. (1964). The structure and development of peat swamps of Sarawak and Brunei. The Journal of Tropical Geography 18, 716.Google Scholar
Anderson, J.A.R., and Muller, J. (1975). Palynological study of a Holocene peat and a Miocene coal deposit from NW Borneo. Review of Palaeobotany and Palynology 19, 291351.CrossRefGoogle Scholar
Anshari, G., Kershaw, A.P., and van der Kaars, S. (2001). A late Pleistocene and Holocene pollen and charcoal record from peat swamp forest, Lake Sentarum Wildlife Reserve, West Kalimantan, Indonesia. Palaeogeography, Palaeoclimatology and Palaeoecology 171, 213228.Google Scholar
Anshari, G., Kershaw, A.P., Kaars, S.V.D., and Jacobsen, G. (2004). Environmental change and peatland forest dynamics in the Lake Sentarum area, West Kalimantan, Indonesia. Journal of Quaternary Science 19, 637655.CrossRefGoogle Scholar
Bellwood, P. (1997). Prehistory of the Indo-Malaysian Archipelago. University of Hawai'i Press, Honolulu.Google Scholar
Bock, C. (1985). The Head-Hunters of Borneo: A Narrative of Travel up the Mahakkam and down the Barito. Oxford Univ. Press, Singapore.Google Scholar
Brookfield, H., Potter, L., and Byron, Y. (1995). In Place of the Forest: Environmental and Socio-Economical Transformation in Borneo and the Eastern Malay Peninsula. United Nations Univ. Press, Tokyo, Japan.Google Scholar
Caratini, C., and Tissot, C. (1988). Paleogeographical evolution of the Mahakam delta in Kalimantan, Indonesia, during the Quaternary and late Pliocene. Review of Palaeobotany and Palynology 55, 217228.CrossRefGoogle Scholar
Chokkalingam, U., Kurniawan, I., and Ruchiat, Y. (2005). Fire, livelihoods, and environmental change in the middle Mahakam peatlands, East Kalimantan. Ecology and Society 10, 1 26 CrossRefGoogle Scholar
Clark, R.L. (1982). Point count estimation of charcoal in pollen preparations and thin sections of sediments. Pollen et Spores 24, 523535.Google Scholar
Goldammer, J., and Siebert, B. (1989). Natural rain forest fires in Eastern Borneo during the Pleistocene and Holocene. Natuurwissenschaften 76, 518520.CrossRefGoogle Scholar
Grove, R.H., and Chappell, J. (2000). El Niño chronology and the history of global crises during the Little Ice Age.Chappell, J., Grove, R.H. El Niño- History and Crisis White Horse Press, Cambridge.534.Google Scholar
Haberle, S.G., Hope, G.S., and van der Kaars, S. (2001). Biomass burning in Indonesia and Papua New Guinea: natural and human induced fire events in the fossil record. Palaeogeography, Palaeoclimatology, Palaeoecology 171, 259268.Google Scholar
Hesp, P.A., Chang, C.H., Hilton, M., Chou, L.M., and Turner, L. (1998). A first tentative Holocene sea level curve for Singapore. Journal of Coastal Research 14, 308314.Google Scholar
Kershaw, A.P., Penny, D., van der Kaars, S., Anshari, G., and Thamotherampili, A. (2001). Vegetation and climate in lowland southeast Asia at the Last Glacial Maximum.Metcalfe, I., Smith, J.M.B., Morwood, M., Davidson, I. Faunal and Floral Migrations and Evolution in SE Asia– Australasia Balkema, Lisse.227236.Google Scholar
Morley, R.J. (1981a). )Development and vegetation dynamics of a lowland ombrogenous peat swamp in Kalimantan Tengah, Indonesia. Journal of Biogeography 8, 383404.Google Scholar
Morley, R.J. (1981b). )The palaeoecology of Tasek Bera, a lowland swamp in Padang, West Malaysia. Singapore Journal Tropical Geography 2, 4956.Google Scholar
Neuzil, S.G. (1997). Onset and rate of peat and carbon accumulation in four domed ombrogenous peat deposits, Indonesia.Rieley, J.O., Page, S.E. Biodiversity and Sustainability of Tropical Peatlands Samara Publishing, Cardigan.5572.Google Scholar
Nichol, J. (1997). Bioclimatic impacts of the 1994 smoke haze event in southeast Asia. Atmospheric Environment 31, 12091219.Google Scholar
Page, S.E., Rieley, J.O., Shotyk, W., and Weiss, D. (1999). Interdependence of peat and vegetation in a tropical peat swamp forest. Philosophical Transactions of the Royal Society of London. Series B 354, 18851897.CrossRefGoogle Scholar
Page, S.E., Siegert, F., Rieley, J.O., Boehm, H.-D.V., Jaya, A., and Limin, S. (2002). The amount of carbon release from peat and forest fires in Indonesia during 1997. Nature 420, 6165.Google Scholar
Potter, L.M. (2002). Forests and grassland, drought and fire: the island of Borneo in the historical environmental record (post 1800).Kershaw, P., David, B., Tapper, N., Penny, D., Brown, J. Bridging Wallace's Line Advances in GeoEcology vol. 34, Catena Verlag, Reiskirchen.339356.Google Scholar
Rieley, J.O., and Page, S. (1997). Biodiversity and Sustainability of Tropical Peatlands. Samara Publishing Ltd., Cardigan.Google Scholar
Staub, J.R., and Esterle, J.S. (1994). Peat accumulating depositional systems of Sarawak, East Malaysia. Sedimentary Geology 89, 91106.Google Scholar
Stuiver, M., Reimer, P.J., and Braziunas, T.F. (1998). High-precision radiocarbon age calibration for terrestrial and marine samples. Radiocarbon 40, 11271151.CrossRefGoogle Scholar
Supardi, , Subekty, A.D., and Neuzil, S.G. (1993). General geology and peat resources of the Siak Kanan and Bengkalis Island peat deposits, Sumatra, Indonesia.Cobb, J.C., Cecil, C.B. Modern and Ancient Coal-Forming Environments Special Paper-Geological Society of America vol. 286, 4562.Google Scholar
Taylor, D., Yen, O.H., Sanderson, P.G., and Dodson, J. (2001). Late Quaternary peat formation and vegetation dynamics in a lowland tropical swamp; Nee Soon, Singapore. Palaeogeography, Palaeoclimatology and Palaeoecology 171, 269287.Google Scholar
Weidemann, D. (2002). Development and extension of a Fire Danger Rating System for the province of East Kalimantan, Indonesia.Final Report, GTZ-MoFEC Integrated Forest Fire Management Project, Samarinda, East Kalimantan.Google Scholar
Weiss, D., Shotyk, W., Rieley, J., Page, S., Gloor, M., Reese, S., and Martinez-Cortizas, A. (2002). The geochemistry of major and selected trace elements in a forested peat bog, Kalimantan, SE Asia, and its implications for past atmospheric dust deposition. Geochimica et Cosmochimica Acta 66, 23072323.Google Scholar
Wüst, R.A.J., and Bustin, R.M. (2004). Late Pleistocene and Holocene development of the interior peat-accumulating basin of tropical Tasek Bera, Peninsular Malaysia. Palaeogeography, Palaeoclimatology and Palaeoecology 211, 241270.Google Scholar
Wüst, R.A.J., Bustin, R.M., and Lavkulich, L. (2003). New classification systems for tropical organic-rich deposits based on studies of the Tasek Bera Basin, Malaysia. Catena 53, 133163.Google Scholar