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International Journal of Wildland Fire International Journal of Wildland Fire Society
Journal of the International Association of Wildland Fire
RESEARCH ARTICLE (Open Access)

GAMBUT field experiment of peatland wildfires in Sumatra: from ignition to spread and suppression

Muhammad A. Santoso https://orcid.org/0000-0001-7936-9211 A E , Eirik G. Christensen https://orcid.org/0000-0001-8927-1437 A , Hafiz M. F. Amin https://orcid.org/0000-0002-6382-757X A B , Pither Palamba https://orcid.org/0000-0002-5847-1548 C , Yuqi Hu A D , Dwi M. J. Purnomo https://orcid.org/0000-0001-6839-7014 A , Wuquan Cui https://orcid.org/0000-0003-2133-1709 A , Agus Pamitran E , Franz Richter https://orcid.org/0000-0003-3035-1533 A , Thomas E. L. Smith https://orcid.org/0000-0001-6022-5314 F , Yulianto S. Nugroho https://orcid.org/0000-0003-3007-9816 E and Guillermo Rein https://orcid.org/0000-0001-7207-2685 A *
+ Author Affiliations
- Author Affiliations

A Department of Mechanical Engineering, and Leverhulme Centre for Wildfires, Environment and Society, Imperial College London, London, SW7 2AZ, UK.

B School of Computing, Engineering & Digital Technologies, Teesside University, Middlesbrough, UK.

C Department of Mechanical Engineering, Universitas Cenderawasih, Jayapura, Indonesia.

D Sichuan Fire Research Institute of the Ministry of Emergency Management, Chengdu, China.

E Department of Mechanical Engineering, Universitas Indonesia, 16424, West Java, Indonesia.

F Department of Geography & Environment, London School of Economics & Political Science, London, UK.

* Correspondence to: g.rein@imperial.ac.uk

International Journal of Wildland Fire 31(10) 949-966 https://doi.org/10.1071/WF21135
Submitted: 6 October 2021  Accepted: 7 August 2022   Published: 28 September 2022

© 2022 The Author(s) (or their employer(s)). Published by CSIRO Publishing on behalf of IAWF. This is an open access article distributed under the Creative Commons Attribution 4.0 International License (CC BY)

Abstract

Peat wildfires can burn over large areas of peatland, releasing ancient carbon and toxic gases into the atmosphere over prolonged periods. These emissions cause haze episodes of pollution and accelerate climate change. Peat wildfires are characterised by smouldering – the flameless, most persistent type of combustion. Mitigation strategies are needed in arctic, boreal, and tropical areas but are hindered by incomplete scientific understanding of smouldering. Here, we present GAMBUT, the largest and longest to-date field experiment of peat wildfires, conducted in a degraded peatland of Sumatra. Temperature, emission and spread of peat fire were continuously measured over 4–10 days and nights, and three major rainfalls. Measurements of temperature in the soil provide field experimental evidence of lethal fire severity to the biological system of the peat up to 30 cm depth. We report that the temperature of the deep smouldering is ~13% hotter than shallow layer during daytime. During night-time, both deep and shallow smouldering had the same level of temperature. The experiment was terminated by suppression with water. Comparison of rainfall with suppression confirms the existence of a critical water column height below which extinction is not possible. GAMBUT provides a unique understanding of peat wildfires at field conditions that can contribute to mitigation strategies.

Keywords: fire behaviour, emission, spread, haze, peat, slash-and-burn, smouldering, suppression.


References

Amin HMF, Hu Y, Rein G (2020) Spatially resolved horizontal spread in smouldering peat combining infrared and visual diagnostics. Combustion and Flame 220, 328–336.
Spatially resolved horizontal spread in smouldering peat combining infrared and visual diagnostics.Crossref | GoogleScholarGoogle Scholar |

Badan Pusat Statistik Kabupaten Rokan Hilir (2015) Rata-Rata Curah Hujan Di Kabupaten Rokan Hilir (mm) 2013–2015. Available at https://rohilkab.bps.go.id/subject/151/iklim.html#subjekViewTab3 [Verified 27 August 2021]

Benscoter BW, Thompson DK, Waddington JM, Flannigan MD, Wotton BM, de Groot WJ, Turetsky MR (2011) Interactive effects of vegetation, soil moisture and bulk density on depth of burning of thick organic soils. International Journal of Wildland Fire 20, 418–429.
Interactive effects of vegetation, soil moisture and bulk density on depth of burning of thick organic soils.Crossref | GoogleScholarGoogle Scholar |

BMKG (2022) Indonesia online climate database. Available at http://dataonline.bmkg.go.id/data_iklim [Verified 14 May 2022]

Chen H, Zhao W, Liu N (2011) Thermal analysis and decomposition kinetics of Chinese forest peat under nitrogen and air atmospheres. Energy & Fuels 25, 797–803.
Thermal analysis and decomposition kinetics of Chinese forest peat under nitrogen and air atmospheres.Crossref | GoogleScholarGoogle Scholar |

Christensen E, Hu Y, Restuccia F, Santoso MA, Huang X, Rein G (2019) Experimental methods and scales in smouldering wildfires. In ‘Fire Effects on Soil Properties’. (Eds P Pereira, J Mataix-Solera, X Ubeda, G Rein, A Cerdà) pp. 267–280. (CSIRO Publishing: Melbourne, Vic., Australia)

Christensen EG, Fernandez-Anez N, Rein G (2020) Influence of soil conditions on the multidimensional spread of smouldering combustion in shallow layers. Combustion and Flame 214, 361–370.
Influence of soil conditions on the multidimensional spread of smouldering combustion in shallow layers.Crossref | GoogleScholarGoogle Scholar |

Cowan DA, Page WG, Butler BW, Blunck DL (2020) Effects of fuel characteristics on horizontal spread rate and ground surface temperatures of smouldering duff. International Journal of Wildland Fire 29, 820–831.
Effects of fuel characteristics on horizontal spread rate and ground surface temperatures of smouldering duff.Crossref | GoogleScholarGoogle Scholar |

Frandsen WH (1987) The influence of moisture and mineral soil on the combustion limits of smoldering forest duff. Canadian Journal of Forest Research 17, 1540–1544.
The influence of moisture and mineral soil on the combustion limits of smoldering forest duff.Crossref | GoogleScholarGoogle Scholar |

Frandsen WH (1997) Ignition probability of organic soils. Canadian Journal of Forest Research 27, 1471–1477.
Ignition probability of organic soils.Crossref | GoogleScholarGoogle Scholar |

Gandois L, Hoyt AM, Hatté C, Jeanneau L, Teisserenc R, Liotaud M, Tananaev N (2019) Contribution of peatland permafrost to dissolved organic matter along a thaw gradient in North Siberia. Environmental Science & Technology 53, 14165–14174.
Contribution of peatland permafrost to dissolved organic matter along a thaw gradient in North Siberia.Crossref | GoogleScholarGoogle Scholar |

Gaveau DLA, Salim MA, Hergoualc’h K, Locatelli B, Sloan S, Wooster M, Marlier ME, Molidena E, Yaen H, DeFries R, Verchot L, Murdiyarso D, Nasi R, Holmgren P, Sheil D (2014) Major atmospheric emissions from peat fires in southeast Asia during non-drought years: evidence from the 2013 Sumatran fires. Scientific Reports 4, 6112
Major atmospheric emissions from peat fires in southeast Asia during non-drought years: evidence from the 2013 Sumatran fires.Crossref | GoogleScholarGoogle Scholar |

Hadden R, Rein G (2011) Burning and water suppression of smoldering coal fires in small-scale laboratory experiments. In ‘Coal and Peat Fires: A Global Perspective’. (Eds GB Stracher, A Prakash, G Rein) pp. 317–326. (Elsevier: Amsterdam, The Netherlands)
| Crossref |

Hartford RA, Frandsen WH (1992) When it’s hot, it’s hot… or maybe it’s not! (surface flaming may not portend extensive soil heating). International Journal of Wildland Fire 2, 139–144.
When it’s hot, it’s hot… or maybe it’s not! (surface flaming may not portend extensive soil heating).Crossref | GoogleScholarGoogle Scholar |

Hoyt AM, Chaussard E, Seppalainen SS, Harvey CF (2020) Widespread subsidence and carbon emissions across southeast Asian peatlands. Nature Geoscience 13, 435–440.
Widespread subsidence and carbon emissions across southeast Asian peatlands.Crossref | GoogleScholarGoogle Scholar |

Hu Y (2019) Experimental Investigation of Peat Fire Emissions and Haze Phenomena. PhD thesis, Imperial College, London, UK.

Hu Y, Fernandez-Anez N, Smith TEL, Rein G (2018) Review of emissions from smouldering peat fires and their contribution to regional haze episodes. International Journal of Wildland Fire 27, 293–312.
Review of emissions from smouldering peat fires and their contribution to regional haze episodes.Crossref | GoogleScholarGoogle Scholar |

Hu Y, Christensen EG, Amin HMF, Smith TEL, Rein G (2019) Experimental study of moisture content effects on the transient gas and particle wmissions from peat fires. Combustion and Flame 209, 408–417.
Experimental study of moisture content effects on the transient gas and particle wmissions from peat fires.Crossref | GoogleScholarGoogle Scholar |

Huang X, Rein G (2014) Smouldering combustion of peat in wildfires: inverse modelling of the drying and the thermal and oxidative decomposition kinetics. Combustion and Flame 161, 1633–1644.
Smouldering combustion of peat in wildfires: inverse modelling of the drying and the thermal and oxidative decomposition kinetics.Crossref | GoogleScholarGoogle Scholar |

Huang X, Rein G (2019) Upward-and-downward spread of smoldering peat fire. Proceedings of the Combustion Institute 37, 4025–4033.
Upward-and-downward spread of smoldering peat fire.Crossref | GoogleScholarGoogle Scholar |

Huang PT, Patel M, Santagata MC, Bobet A (2009) ‘Classification of Organic Soils.’ (Purdue University: West Lafayette, IN, USA)

Huang X, Restuccia F, Gramola M, Rein G (2016) Experimental study of the formation and collapse of an overhang in the lateral spread of smouldering peat fires. Combustion and flame 168, 393–402.
| Crossref |.

Huijnen V, Wooster MJ, Kaiser JW, Gaveau DLA, Flemming J, Parrington M, Inness A, Murdiyarso D, Main B, van Weele M (2016) Fire carbon emissions over maritime Southeast Asia in 2015 largest since 1997. Scientific Reports 6, 26886
Fire carbon emissions over maritime Southeast Asia in 2015 largest since 1997.Crossref | GoogleScholarGoogle Scholar |

Iriana W, Tonokura K, Inoue G, Kawasaki M, Kozan O, Fujimoto K, Ohashi M, Morino I, Someya Y, Imasu R, Rahman MA, Gunawan D (2018) Ground-based measurements of column-averaged carbon dioxide molar mixing ratios in a peatland fire-prone area of central Kalimantan, Indonesia. Scientific Reports 8, 8437
Ground-based measurements of column-averaged carbon dioxide molar mixing ratios in a peatland fire-prone area of central Kalimantan, Indonesia.Crossref | GoogleScholarGoogle Scholar |

IUCN (2017) Peatlands and climate change: issues brief. Available at https://www.iucn.org/resources/issues-briefs/peatlands-and-climate-change [Verified 27 August 2021]

Joosten H (2009) ‘The Global Peatland CO2 Picture: Peatland Status and Drainage Related Emissions in All Countries of the World.’ (Wetlands International) Available at https://unfccc.int/files/kyoto_protocol/application/pdf/draftpeatlandco2report.pdf [Verified 27 August 2021]

Joosten H, Clarke D (2002) ‘Wise Use of Mires and Peatlands’. p. 304. (International Mire Conservation Group and International Peat Society)

Kelly R, Chipman ML, Higuera PE, Stefanova I, Brubaker LB, Hu FS (2013) Recent burning of boreal forests exceeds fire regime limits of the past 10,000 years. Proceedings of the National Academy of Sciences 110, 13055–13060.
Recent burning of boreal forests exceeds fire regime limits of the past 10,000 years.Crossref | GoogleScholarGoogle Scholar |

Könönen M, Jauhiainen J, Laiho R, Kusin K, Vasander H (2015) Physical and chemical properties of tropical peat under stabilised land uses. Mires and Peat 16, 1–13.

Lin S, Cheung YK, Xiao Y, Huang X (2020) Can rain suppress smoldering peat fire? Sci Total Environ 727, 138468
Can rain suppress smoldering peat fire?Crossref | GoogleScholarGoogle Scholar |

Mickler RA, Welch DP, Bailey AD (2017) Carbon emissions during wildland fire on a North American temperate peatland. Fire Ecology 13, 34–57.
Carbon emissions during wildland fire on a North American temperate peatland.Crossref | GoogleScholarGoogle Scholar |

Minasny B, Berglund Ö, Connolly J, Hedley C, de Vries F, Gimona A, Kempen B, Kidd D, Lilja H, Malone B, McBratney A, Roudier P, O’Rourke S, Rudiyanto , Padarian J, Poggio L, ten Caten A, Thompson D, Tuve C, Widyatmanti W (2019) Digital mapping of peatlands – a critical review. Earth-Science Reviews 196, 102870
Digital mapping of peatlands – a critical review.Crossref | GoogleScholarGoogle Scholar |

Muñoz-Rojas M, Bárcenas-Moreno G (2019) Microbiology. In ‘Fire Effects on Soil Properties’. (Eds P Pereira, J Mataix-Solera, X Ubeda, G Rein, A Cerdà) pp. 157–74. (CSIRO Publishing: Melbourne, Vic., Australia)

Murdiyarso D, Saragi-Sasmito MF, Rustini A (2019) Greenhouse gas emissions in restored secondary tropical peat swamp forests. Mitigation and Adaptation Strategies for Global Change 24, 507–520.
Greenhouse gas emissions in restored secondary tropical peat swamp forests.Crossref | GoogleScholarGoogle Scholar |

Ohlemiller TJ (1985) Modeling of smoldering combustion propagation. Progress in Energy and Combustion Science 11, 277–310.
Modeling of smoldering combustion propagation.Crossref | GoogleScholarGoogle Scholar |

Page SE, Siegert F, Rieley JO, Boehm H-DV, Jaya A, Limin S (2002) The amount of carbon released from peat and forest fires in Indonesia during 1997. Nature 420, 61–65.
The amount of carbon released from peat and forest fires in Indonesia during 1997.Crossref | GoogleScholarGoogle Scholar |

Page SE, Rieley JO, Banks CJ (2011) Global and regional importance of the tropical peatland carbon pool. Global Change Biology 17, 798–818.
Global and regional importance of the tropical peatland carbon pool.Crossref | GoogleScholarGoogle Scholar |

Pastor E, Oliveras I, Urquiaga-Flores E, Quintano-Loayza JA, Manta MI, Planas E (2017) A new method for performing smouldering combustion field experiments in peatlands and rich-organic soils. International Journal of Wildland Fire 26, 1040–1052.
A new method for performing smouldering combustion field experiments in peatlands and rich-organic soils.Crossref | GoogleScholarGoogle Scholar |

Paton-Walsh C, Smith TEL, Young EL, Griffith DWT, Guérette ÉA (2014) New emission factors for Australian vegetation fires measured using open-path Fourier Transform Infrared Spectroscopy – Part 1: methods and Australian temperate forest fires. Atmospheric Chemistry and Physics 14, 11313–11333.
New emission factors for Australian vegetation fires measured using open-path Fourier Transform Infrared Spectroscopy – Part 1: methods and Australian temperate forest fires.Crossref | GoogleScholarGoogle Scholar |

Prat-Guitart N, Rein G, Hadden RM, Belcher CM, Yearsley JM (2016a) Effects of spatial heterogeneity in moisture content on the horizontal spread of peat fires. Science of the Total Environment 572, 1422–1430.
Effects of spatial heterogeneity in moisture content on the horizontal spread of peat fires.Crossref | GoogleScholarGoogle Scholar |

Prat-Guitart N, Rein G, Hadden RM, Belcher CM, Yearsley JM (2016b) Propagation probability and spread rates of self-sustained smouldering fires under controlled moisture content and bulk density conditions. International Journal of Wildland Fire 25, 456–465.
Propagation probability and spread rates of self-sustained smouldering fires under controlled moisture content and bulk density conditions.Crossref | GoogleScholarGoogle Scholar |

Purnomo DMJ, Bonner M, Moafi S, Rein G (2021) Using cellular automata to simulate field-scale flaming and smouldering wildfires in tropical peatlands. Proceedings of the Combustion Institute 38, 5119–5127.
Using cellular automata to simulate field-scale flaming and smouldering wildfires in tropical peatlands.Crossref | GoogleScholarGoogle Scholar |

Ramadhan ML, Palamba P, Imran FA, Kosasih EA, Nugroho YS (2017) Experimental study of the effect of water spray on the spread of smoldering in Indonesian peat fires. Fire Safety Journal 91, 671–679.
Experimental study of the effect of water spray on the spread of smoldering in Indonesian peat fires.Crossref | GoogleScholarGoogle Scholar |

Rein G (2013) Smouldering fires and natural fuels. In ‘Fire Phenomena and the Earth System’. (Ed. CM Belcher) pp. 15–33. (John Wiley & Sons: Chichester, UK.)

Rein G (2016) Smoldering combustion. In ‘SFPE Handbook of Fire Protection Engineering’. (Eds MJ Hurley, D Gottuk, JR Hall, K Harada, E Kuligowski, M Puchovsky, J Torero, JM Watts, C Wieczorek) pp. 581–603. (Springer: New York, NY, USA)

Rein G, Huang X (2021) Smouldering wildfires in peatlands, forests and the arctic: challenges and perspectives. Current Opinion in Environmental Science & Health 24, 100296
Smouldering wildfires in peatlands, forests and the arctic: challenges and perspectives.Crossref | GoogleScholarGoogle Scholar |

Rein G, Cleaver N, Ashton C, Pironi P, Torero JL (2008) The severity of smouldering peat fires and damage to the forest soil. CATENA 74, 304–309.
The severity of smouldering peat fires and damage to the forest soil.Crossref | GoogleScholarGoogle Scholar |

Restuccia F, Huang X, Rein G (2017) Self-ignition of natural fuels: can wildfires of carbon-rich soil start by self-heating? Fire Safety Journal 91, 828–834.
Self-ignition of natural fuels: can wildfires of carbon-rich soil start by self-heating?Crossref | GoogleScholarGoogle Scholar |

Rieley J, Page S (2016) Tropical peatland of the world. In ‘Tropical Peatland Ecosystems’. (Eds M Osaki, N Tsuji) pp. 3–32. (Springer: Tokyo, Japan)

Santoso MA, Huang X, Prat-Guitart N, Christensen E, Hu Y, Rein G (2019) Smouldering fires and soils. In ‘Fire Effects on Soil Properties’. (Eds P Pereira, J Mataix-Solera, X Ubeda, G Rein, A Cerdà) pp. 203–216. (CSIRO Publishing: Melbourne, Vic., Australia)

Santoso MA, Cui W, Amin HMF, Christensen EG, Nugroho YS, Rein G (2021) Laboratory study on the suppression of smouldering peat wildfires: effects of flow rate and wetting agent. International Journal of Wildland Fire 30, 378–390.
Laboratory study on the suppression of smouldering peat wildfires: effects of flow rate and wetting agent.Crossref | GoogleScholarGoogle Scholar |

See SW, Balasubramanian R, Rianawati E, Karthikeyan S, Streets DG (2007) Characterization and source apportionment of particulate matter ≤ 2.5 Μm in Sumatra, Indonesia, during a recent peat fire episode. Environmental Science & Technology 41, 3488–3494.
Characterization and source apportionment of particulate matter ≤ 2.5 Μm in Sumatra, Indonesia, during a recent peat fire episode.Crossref | GoogleScholarGoogle Scholar |

Simpson JE, Wooster MJ, Smith TEL, Trivedi M, Vernimmen RRE, Dedi R, Shakti M, Dinata Y (2016) Tropical peatland burn depth and combustion heterogeneity assessed using UAV photogrammetry and airborne LiDAR. Remote Sensing 8, 1000
Tropical peatland burn depth and combustion heterogeneity assessed using UAV photogrammetry and airborne LiDAR.Crossref | GoogleScholarGoogle Scholar |

Smith TEL, Paton-Walsh C, Meyer CP, Cook GD, Maier SW, Russell-Smith J, Wooster MJ, Yates CP (2014) New emission factors for Australian vegetation fires measured using open-path Fourier Transform Infrared Spectroscopy – Part 2: Australian tropical savanna fires. Atmospheric Chemistry and Physics 14, 11335–11352.
New emission factors for Australian vegetation fires measured using open-path Fourier Transform Infrared Spectroscopy – Part 2: Australian tropical savanna fires.Crossref | GoogleScholarGoogle Scholar |

Smith TEL, Evers S, Yule CM, Gan JY (2018) In situ tropical peatland fire emission factors and their variability, as determined by field measurements in Peninsula Malaysia. Global Biogeochemical Cycles 32, 18–31.
In situ tropical peatland fire emission factors and their variability, as determined by field measurements in Peninsula Malaysia.Crossref | GoogleScholarGoogle Scholar |

Tacconi L (2016) Preventing fires and haze in Southeast Asia. Nature Climate Change 6, 640–643.
Preventing fires and haze in Southeast Asia.Crossref | GoogleScholarGoogle Scholar |

Torero JL, Fernandez-Pello AC (1996) Forward smolder of polyurethane foam in a forced air flow. Combustion and Flame 106, 89–109.
Forward smolder of polyurethane foam in a forced air flow.Crossref | GoogleScholarGoogle Scholar |

Turetsky MR, Benscoter B, Page S, Rein G, van der Werf GR, Watts A (2015) Global vulnerability of peatlands to fire and carbon loss. Nature Geoscience 8, 11–14.
Global vulnerability of peatlands to fire and carbon loss.Crossref | GoogleScholarGoogle Scholar |

Usup A, Hashimoto Y, Takahashi H, Hayasaka H (2004) Combustion and thermal characteristics of peat fire in tropical peatland in central Kalimantan, Indonesia. Tropics 14, 1–19.
Combustion and thermal characteristics of peat fire in tropical peatland in central Kalimantan, Indonesia.Crossref | GoogleScholarGoogle Scholar |

Walker XJ, Rogers BM, Veraverbeke S, Johnstone JF, Baltzer JL, Barrett K, Bourgeau-Chavez L, Day NJ, de Groot WJ, Dieleman CM, Goetz S, Hoy E, Jenkins LK, Kane ES, Parisien MA, Potter S, Schuur EAG, Turetsky M, Whitman E, Mack MC (2020) Fuel availability not fire weather controls boreal wildfire severity and carbon emissions. Nature Climate Change 10, 1130–1136.
Fuel availability not fire weather controls boreal wildfire severity and carbon emissions.Crossref | GoogleScholarGoogle Scholar |

Yu ZC (2012) Northern peatland carbonstocks and dynamics: a review. Biogeosciences 9, 4071–4085.
Northern peatland carbonstocks and dynamics: a review.Crossref | GoogleScholarGoogle Scholar |