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Article     |     Next >>   Contents Vol 21(6)

Modelling the potential for prescribed burning to mitigate carbon emissions from wildfires in fire-prone forests of Australia

R. A. Bradstock A B L, M. M. Boer B C K, G. J. Cary B D, O. F. Price A, R. J. Williams B E, D. Barrett F, G. Cook E, A. M. Gill B D, L. B. W. Hutley G, H. Keith D, S. W. Maier G, M. Meyer H, S. H. Roxburgh I and J. Russell-Smith J

A Centre for Environmental Risk Management of Bushfires, University of Wollongong, NSW 2522, Australia.
B Bushfire Cooperative Research Centre, East Melbourne, Vic. 3002, Australia.
C Ecosystems Research Group, School of Plant Biology M090, The University of Western Australia, 35 Stirling Highway, Crawley, WA 6009, Australia.
D Fenner School of Environment and Society, Australian National University, Canberra, ACT 0200, Australia.
E CSIRO Ecosystems Sciences, CSIRO Climate Adaptation Flagship and CSIRO Sustainable Agriculture Flagship, PMB 44 Winnellie, NT 0822, Australia.
F Centre for Water in the Minerals Industry, Sustainable Minerals Institute, The University of Queensland, Brisbane, Qld 4072, Australia.
G School of Environmental and Life Sciences, Charles Darwin University, Darwin, NT 0909, Australia.
H CSIRO Marine and Atmospheric Research, Aspendale, Vic. 3195, Australia.
I CSIRO Sustainable Agriculture Flagship and CSIRO Ecosystems Sciences, GPO Box 284, ACT 2601, Australia.
J Bushfires NT, Winnellie, NT 0820, Australia.
K Present address: Hawkesbury Institute for the Environment – University of Western Sydney, Richmond, 2753 NSW, Australia.
L Corresponding author. Email: rossb@uow.edu.au

International Journal of Wildland Fire 21(6) 629-639 http://dx.doi.org/10.1071/WF11023
Submitted: 9 February 2011  Accepted: 24 January 2012   Published: 5 July 2012

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Prescribed fire can potentially reduce carbon emissions from unplanned fires. This potential will differ among ecosystems owing to inherent differences in the efficacy of prescribed burning in reducing unplanned fire activity (or ‘leverage’, i.e. the reduction in area of unplanned fire per unit area of prescribed fire). In temperate eucalypt forests, prescribed burning leverage is relatively low and potential for mitigation of carbon emissions from unplanned fires via prescribed fire is potentially limited. Simulations of fire regimes accounting for non-linear patterns of fuel dynamics for three fuel types characteristic of eucalypt forests in south-eastern Australia supported this prediction. Estimated mean annual fuel consumption increased with diminishing leverage and increasing rate of prescribed burning, even though average fire intensity (prescribed and unplanned fires combined) decreased. The results indicated that use of prescribed burning in these temperate forests is unlikely to yield a net reduction in carbon emissions. Future increases in burning rates under climate change may increase emissions and reduce carbon sequestration. A more detailed understanding of the efficacy of prescribed burning and dynamics of combustible biomass pools is required to clarify the potential for mitigation of carbon emissions in temperate eucalypt forests and other ecosystems.

Additional keywords: Eucalyptus, fire management, fire regimes, fuel.


Boer MM, Sadler RJ, Wittkuhn R, McCaw L, Grierson PF (2009) Long-term impacts of prescribed burning on regional extent and incidence of wildfires – evidence from 50 years of active fire management in SW Australian forests. Forest Ecology and Management 259, 132–142.
CrossRef |

Bowman DMJS, Balch JK, Artaxo P, Bond WJ, Carlson JM, Cochrane MA, D’Antonio CM, DeFries RS, Doyle JC, Harrison SP, Johnston FH, Keeley JE, Krawchuk MA, Kull CA, Marston JB, Moritz MA, Prentice C, Roos CI, Scott AC, Swetnam TW, van der Werf GR, Pyne SJ (2009) Fire in the Earth system. Science 324, 481–484.
CrossRef | CAS |

Bradstock RA (2010) A biogeographic model of fire regimes in Australia: contemporary and future implications. Global Ecology and Biogeography 19, 145–158.
CrossRef |

Bradstock RA, Auld TD (1995) Soil temperatures during experimental bushfires in relation to fire intensity: consequences for legume germination and fire-management in south-eastern Australia. Journal of Applied Ecology 32, 76–84.
CrossRef |

Bradstock RA, Williams RJ (2009) Can Australian fire regimes be managed for carbon benefits? New Phytologist 183, 931–934.
CrossRef |

Bradstock RA, Hammill K, Collins L, Price O (2010) Effects of weather, fuel and terrain on fire severity in topographically diverse landscapes of south-eastern Australia. Landscape Ecology 25, 607–619.
CrossRef |

Bradstock RA, Cary GJ, Davies I, Lindenmayer DB, Price OF, Williams RJ (2012) Wildfires, fuel treatment and risk mitigation in Australian eucalypt forests: insights from landscape-scale simulation. Journal of Environmental Management 105, 66–75.
CrossRef | CAS |

Campbell JL, Harmon ME, Mitchell SR (2011) Can fuel-reduction treatments really increase forest carbon storage in the western US by reducing future fire emissions? Frontiers in Ecology and the Environment
CrossRef |

Catchpole W (2002) Fire properties and burn patterns in heterogeneous landscapes. In ‘Flammable Australia: the Fire Regimes and Biodiversity of a Continent’. (Eds RA Bradstock, JE Williams, AM Gill) pp. 50–75. (Cambridge University Press: Cambridge, UK)

Cheney NP (1981) Fire behaviour. In ‘Fire and the Australian Biota’. (Eds AM Gill, RH Groves, IR Noble) pp. 151–176. (Australian Academy of Science: Canberra, ACT)

Doerr SH, Shakesby RA, Blake WH, Chafer CJ, Humphreys GS, Wallbrink PJ (2006) Effects of differing wildfire severities on soil wettability and implications for hydrological responses. Journal of Hydrology 319, 295–311.
CrossRef |

Fernandes PM, Bothello HS (2003) A review of prescribed burning effectiveness in fire hazard reduction. International Journal of Wildland Fire 12, 117–128.
CrossRef |

Finney MA, Seli RC, McHugh CW, Ager AA, Bahro B, Agee JK (2007) Simulation of long-term landscape-level fuel treatment effects on large wildfires. International Journal of Wildland Fire 16, 712–727.
CrossRef |

Gill AM, Catling PC (2002) Fire regimes and biodiversity of forested landscapes of southern Australia. In ‘Flammable Australia: the Fire Regimes and Biodiversity of a Continent’. (Eds RA Bradstock, JE Williams, AM Gill) pp. 351–369. (Cambridge University Press: Cambridge, UK)

Gill AM, Christian KR, Moore PHR, Forrester RI (1987) Bushfire incidence, fire hazard and fuel reduction burning. Australian Journal of Ecology 12, 299–306.
CrossRef |

Gill AM, Ryan PG, Moore PHR, Gibson M (2000) Fire regimes of World Heritage Kakadu National Park, Australia. Austral Ecology 25, 616–625.

Hopmans P (2003) Effects of repeated low-intensity fire on carbon, nitrogen and phosphorus in the soils of a mixed-eucalypt foothill forest in south-eastern Australia. Research Report Number 60. (Victorian Department of Sustainability and Environment: Melbourne)

Hurteau MD, North M (2009) Fuel treatment effects on tree-based forest carbon storage and emissions under modeled wildfire scenarios. Frontiers in Ecology and the Environment 7, 409–414.
CrossRef |

Hurteau MD, Koch GW, Huntgate BA (2008) Carbon protection and fire risk reduction: toward a full accounting of forest carbon offsets. Frontiers in Ecology and the Environment 6, 493–498.
CrossRef |

Keeley JE, Zedler PH (2009) Large, high-intensity fire events in southern California shrublands: debunking the fine-grain age patch model. Ecological Applications 19, 69–94.
CrossRef |

Keith H (1991) Effects of fire and fertilisation on nitrogen cycling and tree growth in a subalpine eucalypt forest. PhD dissertation, Australian National University, Canberra.

Keith H, Mackey BG, Lindenmayer DB (2009) Re-evaluation of forest biomass carbon stocks and lessons from the world’s most carbon-dense forests. Proceedings of the National Academy of Sciences of the United States of America 106, 11 635–11 640.

Keith H, Leuning RL, Jacobsen KL, Cleugh HA, van Gorsel E, Raison RJ, Medlyn BE, Winter A, Keitel C (2009b) Multiple measurements constrain estimates of net carbon exchange by a Eucalypt forest. Agricultural and Forest Meteorology 149, 535–558.
CrossRef |

King KJ, Bradstock RA, Cary G, Chapman C, Marsden-Smedley J (2008) An investigation into the relative importance of fine-scale fuel mosaics on reducing fire risk in south-west Tasmania, Australia. International Journal of Wildland Fire 17, 421–430.
CrossRef |

King KJ, de Ligt RM, Cary GJ (2011) Fire and carbon dynamics under climate change in south-eastern Australia: insights from FullCAM and FIRESCAPE modelling. International Journal of Wildland Fire 20, 563–577.

Krivtsov V, Vigy C, Legga T, Curtc E, Rigolot I, Lecomteb M, Jappiotc C, Lampin-Maillet PF, Pezzatti GB (2009) Fuel modelling in terrestrial ecosystems: an overview in the context of the development of an object-orientated database for wildfire analysis. Ecological Modelling 220, 2915–2926.
CrossRef |

Liedloff AC, Cook GD (2007) Modelling the effects of rainfall variability and fire on tree populations in an Australian tropical savanna with the FLAMES simulation model. Ecological Modelling 201, 269–282.
CrossRef |

Loehle C (2004) Applying landscape principles to fire hazard reduction. Forest Ecology and Management 198, 261–267.
CrossRef |

Mitchell SR, Harmon ME, O’Connell KEB (2009) Forest fuel reduction alters fire severity and long-term carbon storage in three Pacific Northwest ecosystems. Ecological Applications 19, 643–655.
CrossRef |

Morrison DA, Buckney RT, Bewick BJ, Cary CJ (1996) Conservation conflicts over burning bush in south-eastern Australia. Biological Conservation 76, 167–175.
CrossRef |

Narayan C, Fernandes PM, van Brusselen J, Schuck A (2007) Potential for CO2 emissions mitigation in Europe through prescribed burning in the context of the Kyoto Protocol. Forest Ecology and Management 251, 164–173.
CrossRef |

Ooi MKJ, Whelan RJ, Auld TD (2006) Persistence of obligate-seeding species at the population scale: effects of fire intensity, fire patchiness and long fire-free intervals. International Journal of Wildland Fire 15, 261–269.
CrossRef |

Penman TD, Kavanagh RP, Binns DL, Melick DR (2007) Patchiness of prescribed burns in dry sclerophyll forests in south-eastern Australia. Forest Ecology and Management 252, 24–32.
CrossRef |

Price OF, Bradstock RA (2010) The effect of fuel age on the spread of fire in sclerophyll forest in the Sydney region of Australia. International Journal of Wildland Fire 19, 35–45.
CrossRef |

Price OF, Bradstock RA (2011) The influence of weather and fuel management on the annual extent of unplanned fires in the Sydney region of Australia. International Journal of Wildland Fire 20, 142–151.

Raison RJ, Woods PV, Khanna PK (1983) Dynamics of fine fuels in recurrently burnt eucalypt forests. Australian Forestry 46, 294–302.

Russell-Smith J, Whitehead PJ, Cooke P (2009a) ‘Culture, Ecology and Economy of Fire Management in North Australian Savannas: Rekindling the Wurrk Tradition.’ (CSIRO Publishing: Melbourne)

Russell-Smith J, Murphy BP, Meyer CP, Cook GD, Maier S, Edwards AC, Schatz J, Brocklehurst P (2009b) Improving estimates of savanna burning emissions for greenhouse accounting in northern Australia: limitations, challenges, applications. International Journal of Wildland Fire 18, 1–18.
CrossRef | CAS |

Specht RL, Specht A (1999) ‘Australian Plant Communities: Dynamics of Structure, Growth and Biodiversity.’ (Oxford University Press: Melbourne)

Tozer MG, Auld TD (2006) Soil heating and germination: investigations using leaf scorch on graminoids and experimental seed burial. International Journal of Wildland Fire 15, 509–516.
CrossRef |

van der Werf GR, Randerson JT, Giglio L, Collatz GJ, Kasibhatla PS, Arellano AF (2006) Inter-annual variability in global biomass burning emissions from 1997 to 2004. Atmospheric Chemistry and Physics 6, 3423–3441.
CrossRef | CAS |

van Gorsel E, Leuning R, Cleugh HA, Keith H, Kirschbaum MUF, Suni T (2008) Application of an alternative method to derive reliable estimates of night-time respiration from eddy covariance measurements in moderately complex topography. Agricultural and Forest Meteorology 148, 1174–1180.
CrossRef |

Wiedinmyer C, Hurteau MD (2010) Prescribed fire as a means of reducing forest carbon emissions in the western United States. Environmental Science & Technology 44, 1926–1932.
CrossRef | CAS |

Williams RJ, Bradstock RA, Cary GJ, Enright NJ, Gill AM, Liedloff AC, Lucas C, Whelan RJ, Andersen AN, Bowman DMJS, Clarke PJ, Cook GD, Hennessy KJ, York A (2009) Interactions between climate change, fire regimes and biodiversity in Australia – a preliminary assessment. Report to the Department of Climate Change and Department of Environment, Water, Heritage and the Arts. (Canberra, ACT)

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