Climate anomalies, Indonesian vegetation fires and terrestrial carbon emissions

  • Daniel MurdiyarsoEmail author
  • Erna S. Adiningsih
Original Article


There was a widespread misconception about the causes of vegetation and land fires in Indonesia. At a certain point, the public perceived that fires and the associated haze pollution were primarily caused by smallholders' agricultural activities. In fact, there was a variety of land-use activities including large-scale land clearing following deforestation for further land development. El Niño events and the associated dry weather were sometimes quoted by officials and the media as the cause of fires. The fire episodes from 1980 to 2000 were analysed in connection with climate anomalies and the implementation of land-use policies related to forest conversions. The analysis employs long-term climatic and sea surface temperature data to reconstruct climate distributions and anomalies including Southern Oscillation Index (SOI), Sea Surface Temperature (SST) and Outgoing Long-wave Radiation (OLR). In this study, the terrestrial carbon emissions from vegetation fires were estimated based on official statistical data on area burnt. The possible incentives for sustainable land management were discussed in the light of fire prevention. The underlying cause neglected in the discussion of Indonesian vegetation fires was forest and land development policy. Legitimated in the early 1980s, it drove massive forest conversions and the use of fires for land clearing. El Niño Southern Oscillation (ENSO) provided dry weather suitable for biomass burning and widespread fire, but it was hardly the cause of fires. The estimate of area burnt in the big fires in 1997 was about 11.6 Mha, resulting in carbon release of 1.45 Gt, equivalent to 0.73 ppmv of CO2, or almost half the annual global atmospheric CO2 growth. Based on the current carbon market price such emissions by the 1997 fire episode were worth around US$ 3.6 billion.


Carbon market Deforestation Land management Peatlands Underlying causes 


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  1. BAPPENAS (1999) Planning for fire prevention and drought management project. Volume 2. Cause, Extent, Impact, and Cost of 1997/1998 Fires and Drought, JakartaGoogle Scholar
  2. Bompard JM, Guizol P (1999) Land management in the province of South Sumatra, Indonesia: fanning the flames: the institutional causes of vegetation fires, Jakarta. Forest Fire Prevention and Control Project, EU-Government of IndonesiaGoogle Scholar
  3. Chang CT, Kiyotoshi T (1994) Diurnal variation of OLR in the vicinity of the South China Sea: effect of intraseasonal oscillation. Monthly Weather Review 123:566–577Google Scholar
  4. Goldammer JG, Rufelds HC, Malingreau JP, Yokelson R, Abberger H, Manila A (1998) The ASEAN fire forum: results of the working group discussions. In proceedings, AIFM conference on transboundary pollution and the sustainability of tropical forests: towards wise forest fire management. 2–4 December 1996, Kuala Lumpur, ASEAN Institute for Forest ManagementGoogle Scholar
  5. Goldammer JG, Siebert B (1990) The impacts of droughts and forest fires on tropical lowland rainforest of East Kalimantan. In: Goldammer JG (ed) Fire in the Tropical Biota: Ecosystem Processes and Global Challenges. Ecological Studies 84. Springer-Verlag, BerlinGoogle Scholar
  6. Hairiah K, Sitompul SM (2000) Estimate of above and below ground biomass in the humid tropics. Bogor, IC-SEA Working Document No. 4/2000Google Scholar
  7. Hoffmann AA, Hinrichs A, Siegert F (1999) Fire damage in East Kalimantan in 1997/1998 Related to Land-use and Vegetation Classes: Satellite Radar Inventory Results and Proposal for Further Actions. Samarinda, Indonesia, MoFEC, GTZ and KfWGoogle Scholar
  8. Houghton JT, Ding Y, Griggs DJ, Noguer M, van der Linden PJ, Dai X, Maskell K, Johnson CA (eds) Climate change 2001: The Scientific Basis. Contribution of Working Group I to the Third Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge University Press, CambridgeGoogle Scholar
  9. Jepson P, Jarvie JK, MacKinnon K, Monk KA (2001) The end for Indonesia's lowland forests? Science 292:859–861CrossRefGoogle Scholar
  10. Jordan CF (1983) Tropical rain forest ecosystems. In Golley FB (ed) Ecosystems of the World 14. Elsevier, Amsterdam, pp 117–135Google Scholar
  11. Ketterings QM (2000) Fire as a Land Management Tool in Sepunggur, Sumatra, Indonesia: Can Farmers Do without It? Ph.D. Dissertation, Iowa State UniversityGoogle Scholar
  12. Ketterings QM, Wibowo TT, van Noordwijk M, Penot E (1999) Farmers perspectives on slash-and-burn as land clearing method for small-scale rubber producers in Sepunggur, Jambi Province, Sumatra, Indonesia. Forest Ecology and Management 120:157–169CrossRefGoogle Scholar
  13. Legg CA, Laumonier Y (1999) Fire in Indonesia, 1997: a remote sensing perspective. Ambio 28:479–485Google Scholar
  14. Leining CR (2000) The eligibility of land-use, land-use change and forestry projects under the clean development mechanism. CDM dialogue paper. Center for clean air policy. Washington, DCGoogle Scholar
  15. Liew SC, Kwoh LK, Lim OK, Lim H (2001) Remote sensing of fire and haze. In: Eaton P, Radojevic M (eds) Forest fires and regional haze in Southeast Asia. Nova Science Publishers, New York, pp 67–89Google Scholar
  16. MoF (1998) Luas kebakaran hutan di Indonesia,
  17. MoFEC (1997) Forest Inventory and Mapping Programme. Jakarta, Indonesia, Ministry of Forestry and Estate CropsGoogle Scholar
  18. Murdiyarso D, Lebel L, Gintings AN, Tampubolon SMH, Heil A, Wasson M (2004) Policy responses to complex environmental problems: insights from a science-policy activity on transboundary haze from vegetation fires in Southeast Asia. J Agriculture, Ecosystems& Environment 104:47–56CrossRefGoogle Scholar
  19. Murdiyarso D, van Noordwijk M, Wasrin UR, Tomich TP, Gillison A (2002) Environmental benefits and sustainable land-use in Jambi transect, Sumatra, Indonesia. J Vegetation Science 13:429–438CrossRefGoogle Scholar
  20. Murdiyarso D, Widodo M, Suyamto D (2002) Fire risks in forest carbon project in Indonesia. J Science in China 5:65–74Google Scholar
  21. Noble I, Scholes RJ (2001) Sinks and the Kyoto Protocol. Climate Policy 1:5–25CrossRefGoogle Scholar
  22. Page SE, Siegert F, Rieley JO, v Boehm HD, Jaya A (2002) The amount of carbon released from peat and forest fires in Indonesia during 1997. Nature 420:61–65CrossRefGoogle Scholar
  23. Pittock AB (1974) Global interactions in stratosphere and troposphere. In: Proc. Int. Conf. Structure, Composition and General Circulation of Upper and Lower Atmosphere and Possible Anthropogenic Perturbations. Canberra. The Australian Academy of Sciences, pp. 716–726Google Scholar
  24. Potter L, Lee J (1998) Tree planting in Indonesia: trend, impacts and direction. Occasional Paper No. 18, Bogor, Center for International Forestry ResearchGoogle Scholar
  25. Schindler L, Thoma W, Panzer K (1989) The Kalimantan Forest Fire of 1982–3 in East Kalimantan. Part I: The fire, the effect, the damage and technical solution. Jakarta, FR Report No. 5. GTZ/ITTOGoogle Scholar
  26. Schweithelm J (1999) The Fire This Time. An Overview of Indonesia's Forest Fires in 1997/98, Jakarta. WWF-Indonesia ProgrammeGoogle Scholar
  27. SKEPHI (1992) Special Report on Forest Fire. Setiakawan 7:27–59Google Scholar
  28. Siegert F, Hoffmann AA (2000) The 1998 forest fires in East Kalimantan (Indonesia): a quantitative evaluation using high resolution, multitemporal ERS-2 SAR images and NOAA-AVHRR hotspot data. Remote Sensing Environment 72:64–77CrossRefGoogle Scholar
  29. Stolle F (2003) Land-use as Driver of Vegetation Fires in Indonesia: A spatial modelling approach to identify and quantify causes of fire. Unpublished Ph.D. Dissertation. Université Catholique de Louvain, Louvain, BelgiumGoogle Scholar
  30. Tacconi L (2003) Fires in Indonesia: Causes, costs and policy implications. Occasional Paper No. 38. Bogor, Indonesia, Center for International Forestry ResearchGoogle Scholar
  31. Tangang FT, Tang B, Monahan HA, Hsieh WW (1998) Forecasting ENSO events: a neural network– extended EOF approach. Journal of Climate 11:29–41CrossRefGoogle Scholar
  32. Tomich TP, Fagi AM, de Foresta H, Michon G, Murdiyarso D, Stolle F, van Noordwijk M (1998) Indonesia's fires: smoke as a problem, smoke as a symptom. Agroforestry Today (January–March), 4–7Google Scholar
  33. Trenberth KE, Hoar TJ (1997) El Nino and climate change. Geophysics Research Letter 24:3057–3060CrossRefGoogle Scholar
  34. Woodruff SD, Slutz RJ, Jenne RL, Steurer PM (1987) A comprehensive ocean-atmosphere data set. Bulletin of American Meteorological Society 6:1239–1250CrossRefGoogle Scholar
  35. World Bank (1999) Deforestation in Indonesia: a preliminary view of the situation in Sumatra and Kalimantan. Washington, DCGoogle Scholar
  36. World Bank (2000) Indonesia, Environmental and Natural Resource Management in a Time of Transition. Washington, DCGoogle Scholar

Copyright information

© Springer Science+Business Media, Inc. 2006

Authors and Affiliations

  1. 1.Center for International Forestry Research (CIFOR)JakartaIndonesia
  2. 2.National Institute of Aeronautics and Space (LAPAN)JakartaIndonesia

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