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RESEARCH ARTICLE (Open Access)
Contents Vol 33(4)

Modification of the Rothermel model parameters – the rate of surface fire spread of Pinus koraiensis needles under no-wind and various slope conditions

Daotong Geng A , Guang Yang A * , Jibin Ning A , Ang Li B * , Zhaoguo Li A , Shangjiong Ma A , Xinyu Wang A and Hongzhou Yu https://orcid.org/0000-0002-9903-6403 A
+ Author Affiliations
- Author Affiliations

A Key Laboratory of Sustainable Forest Ecosystem Management-Ministry of Education, College of Forestry, Northeast Forestry University, Harbin, Heilongjiang 150040, China.

B College of Forestry, Inner Mongolia Agricultural University, Hohhot 010019, China.

* Correspondence to: lx_yg@163.com, fcla@imau.edu.cn

International Journal of Wildland Fire 33, WF23118 https://doi.org/10.1071/WF23118
Submitted: 18 July 2023  Accepted: 19 March 2024  Published: 8 April 2024

© 2024 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-NonCommercial-NoDerivatives 4.0 International License (CC BY-NC-ND)

Abstract

Background

The prediction accuracy for the rate of surface fire spread varies in different regions; thus, increasing the prediction accuracy for local fuel types to reduce the destructive consequences of fire is critically needed.

Aims

The objective of this study is to improve the Rothermel model’s accuracy in predicting the ROS for surface fuel burning in planted forests of Pinus koraiensis in the eastern mountains of north-east China.

Methods

Fuel beds with various fuel loads and moisture content was constructed on a laboratory burning bed, 276 combustion experiments were performed under multiple slope conditions, and the ROS data from the combustion experiments were used to modify the related parameters in the Rothermel model.

Results

The surface fire spread rate in Pinus koraiensis plantations was directly predicted using the Rothermel model but had significant errors. The Rothermel model after modification predicted the following: MRE = 25.09%, MAE = 0.46 m min−1, and R2 = 0.80.

Conclusion

The prediction accuracy of the Rothermel model was greatly enhanced through parameter tuning based on in-lab combustion experiments

Implications

This study provides a method for the local application of the Rothermel model in China and helps with forest fire fighting and management in China.

Keywords: fuel loads, fuel moisture, modified parameters, Pinus koraiensis, ROS, Rothermel model, slope, surface fire.

References

Abram NJ, Henley BJ, Sen Gupta A, Lippmann TJR, Clarke H, Dowdy AJ, Sharples JJ, Nolan RH, Zhang T, Wooster MJ, Wurtzel JB, Meissner KJ, Pitman AJ, Ukkola AM, Murphy BP, Tapper NJ, Boer MM (2021) Connections of climate change and variability to large and extreme forest fires in southeast Australia. Communications Earth & Environment 2, 1-17.
| Crossref | Google Scholar |

Albini FA (1976a) Estimating wildfire behaviour and effects. Vol. 30. (Department of Agriculture, Forest Service, Intermountain Forest and Range Experiment Station)

Albini FA (1976b) Computer-based models of wildland fire behaviour: a user’s manual. (Intermountain Forest and Range Experiment Station, Forest Service, US Department of Agriculture)

Alexander ME, Cruz MG (2013) Limitations on the accuracy of model predictions of wildland fire behaviour: a state-of-the-knowledge overview. Forestry Chronicle 89, 370-381.
| Crossref | Google Scholar |

Anderson HE (1982) Aids to determining fuel models for estimating fire behavior. General Technical Report INT-122. (USDA Forest Service, Intermountain Forest and Range Experiment Station)

Andrews PL (2007) BehavePlus fire modeling system: past, present, and future. In ‘Proceedings of 7th Symposium on Fire and Forest Meteorological Society’, 23–25. October 2007, Bar Harbor, ME. Paper J2.1. (American Meteorological Society: Boston, MA, USA) Available at https://ams.confex.com/ams/pdfpapers/126669.pdf

Andrews PL (2014) Current status and future needs of the BehavePlus Fire Modeling System. International Journal of Wildland Fire 23, 21-33.
| Crossref | Google Scholar |

Andrews PL (2018) The Rothermel surface fire spread model and associated developments: A comprehensive explanation. (United States Department of Agriculture, Forest Service, Rocky Mountain Research Station)

Andrews PL, Cruz MG, Rothermel RC (2013) Examination of the wind speed limit function in the Rothermel surface fire spread model. International Journal of Wildland Fire 22, 959-969.
| Crossref | Google Scholar |

Bachmann A, Allgöwer B (2002) Uncertainty propagation in wildland fire behaviour modelling. International Journal of Geographical Information Science 16, 115-127.
| Crossref | Google Scholar |

Benali A, Ervilha AR, Sá AC, Fernandes PM, Pinto RM, Trigo RM, Pereira JMC (2016) Deciphering the impact of uncertainty on the accuracy of large wildfire spread simulations. Science of the Total Environment 569–570, 73-85.
| Crossref | Google Scholar | PubMed |

Bowman DMJS, Williamson GJ, Abatzoglou JT, Kolden CA, Cochrane MA, Smith AMS (2017) Human exposure and sensitivity to globally extreme wildfire events. Nature Ecology & Evolution 1, 0058.
| Crossref | Google Scholar | PubMed |

Byram GM (1966) Scaling laws for modeling mass fires. Pyrodynamics 4, 271-284.
| Google Scholar |

Canadian Interagency Forest Fire Center (2003) ‘Glossary of Forest Fire Management Terms.’ 61 p. (Winnipge, MB, Canada) Available at http://bcwildfire.ca/MediaRoom/Backgrounders/2003_Fire_Glossary.pdf2003

Catchpole EA, Catchpole WR, Rothermel RC (1993) Fire behavior experiments in mixed fuel complexes. International Journal of Wildland Fire 3, 45-57.
| Crossref | Google Scholar |

Catchpole WR, Catchpole EA, Butler BW, Rothermel RC, Latham DJ (1998) Rate of spread of free-burning fires in woody fuels in a wind tunnel. Combustion Science & Technology 131, 1-37.
| Crossref | Google Scholar |

Cruz MG, Alexander ME (2013) Uncertainty associated with model predictions of surface and crown fire rates of spread. Environmental Modelling & Software 47, 16-28.
| Crossref | Google Scholar |

Cruz MG, Alexander ME, Sullivan AL, Gould JS, Kilinc M (2018a) Assessing improvements in models used to operationally predict wildland fire rate of spread. Environmental Modelling & Software 105, 54-63.
| Crossref | Google Scholar |

Cruz MG, Sullivan AL, Gould JS, Hurley RJ, Plucinski MP (2018b) Got to burn to learn: the effect of fuel load on grassland fire behaviour and its management implications. International Journal of Wildland Fire 27, 727-741.
| Crossref | Google Scholar |

Dittrich R, McCallum S (2020) How to measure the economic health cost of wildfires – A systematic review of the literature for northern America. International Journal of Wildland Fire 29, 961-973.
| Crossref | Google Scholar |

Driscoll DA, Lindenmayer DB, Bennett AF, Bode M, Bradstock RA, Cary GJ, Clarke MF, Dexter N, Fensham R, Friend G, Gill M, James S, Kay G, Keith DA, MacGregor C, Russell-Smith J, Salt D, Watson JEM, Williams RJ, York A (2010) Fire management for biodiversity conservation: key research questions and our capacity to answer them. Biological Conservation 143, 1928-1939.
| Crossref | Google Scholar |

Dupuy JL, Maréchal J (2011) Slope effect on laboratory fire spread: contribution of radiation and convection to fuel bed preheating. International Journal of Wildland Fire 20, 289-307.
| Crossref | Google Scholar |

Dupuy JL, Maréchal J, Portier D, Valette JC (2011) The effects of slope and fuel bed width on laboratory fire behaviour. International Journal of Wildland Fire 20, 272-288.
| Crossref | Google Scholar |

Fernandes PM (2009) Combining forest structure data and fuel modelling to classify fire hazard in Portugal. Annals of Forest Science 66, 415.
| Crossref | Google Scholar |

Filkov AI, Ngo T, Matthews S, Telfer S, Penman TD (2020) Impact of Australia’s catastrophic 2019/20 bushfire season on communities and environment. Retrospective analysis and current trends. Journal of Safety Science and Resilience 1, 44-56.
| Crossref | Google Scholar |

Finney MA (1998) FARSITE: Fire Area Simulator – model development and evaluation. Research Paper RMRS-RP-4. (USDA Forest Service, Rocky Mountain Research Station)

Finney MA, McAllister SS, Forthofer JM, Grumstrup TP (2021) ‘Wildland fire behaviour: dynamics, principles and processes.’ (CSIRO Publishing: Melbourne, Vic., Australia)

Fons WL (1946) Analysis of fire spread in light forest fuels. Journal of Agricultural Research 72, 93-121.
| Google Scholar |

Frandsen WH (1971) Fire spread through porous fuels from the conservation of energy. Combustion & Flame 16, 9-16.
| Crossref | Google Scholar |

Gould JS, Sullivan AL (2020) Two methods for calculating wildland fire rate of forward spread. International Journal of Wildland Fire 29, 272-281.
| Crossref | Google Scholar |

Jimenez E, Hussaini MY, Goodrick S (2008) Quantifying parametric uncertainty in the Rothermel model. International Journal of Wildland Fire 17, 638-649.
| Crossref | Google Scholar |

Johnston FH, Henderson SB, Chen Y, Randerson JT, Marlier M, Defries RS, Kinney P, Bowman DM, Brauer M (2012) Estimated global mortality attributable to smoke from landscape fires. Environment Health Perspectives 120, 695-701.
| Crossref | Google Scholar | PubMed |

Keane RE, Reeves M (2011) Use of expert knowledge to develop fuel maps for wildland fire management. In ‘Expert Knowledge and Its Application in Landscape Ecology’. (Eds AH Perera, C Drew, C Johnson, et al.) pp. 211–228. (Springer) 10.1007/978-1-s4614-1034-8_11

Koopmans E, Fyfe T, Eadie M, Pelletier CA (2020) Exploring prevention and mitigation strategies to reduce the health impacts of occupational exposure to wildfires for wildland firefighters and related personnel: protocol of a scoping study. Systematic Reviews 9, 119.
| Crossref | Google Scholar | PubMed |

Li H, Liu N, Xie X, Zhang L, Yuan X, He Q, Viegas DX (2021) Effect of fuel bed width on upslope fire spread: an experimental study. Fire Technology 57, 1063-1076.
| Crossref | Google Scholar |

Liu N, Wu J, Chen H, Xie X, Zhang L, Yao B, Zhu J, Shan Y (2014) Effect of slope on spread of a linear flame front over a pine needle fuel bed: experiments and modelling. International Journal of Wildland Fire 23, 1087-1096.
| Crossref | Google Scholar |

Lozano J, Tachajapong W, Pan H, Swanson A, Kelley C, Princevac M, Mahalingam S (2008) Experimental investigation of the velocity field in a controlled wind-aided propagating fire using particle image velocimetry. Fire Safety Science 9, 255-266.
| Crossref | Google Scholar |

Manzello SL (2020) ‘Encyclopedia of Wildfires and Wildland-Urban Interface (WUI) Fires.’ (Springer International Publishing AG: Cham, Switzerland)

McCaw WL, Gould JS, Cheney NP, Ellis P, Anderson WR (2012) Changes in behaviour of fire in dry eucalypt forest as fuel increases with age. Forest Ecology and Management 271, 170-181.
| Crossref | Google Scholar |

Mendes-Lopes J, Ventura J, Amaral J (1998) Rate of spread and flame characteristics in a bed of pine needles. In ‘Proceedings of the III International Conference on Forest Fire Research – 14th Conference on Fire and Forest Meteorology’. Vol. 1, 16–20 November 1998, Luso, Portugal. (Ed. DX Viegas) pp. 497–511.

Ning J, Yang G, Liu X, Geng D, Wang L, Li Z, Zhang Y, Di X, Sun L, Yu H (2022) Effect of fire spread, flame characteristic, fire intensity on particulate matter 2.5 released from surface fuel combustion of Pinus koraiensis plantation – A laboratory simulation study. Environment International 166, 107352.
| Crossref | Google Scholar | PubMed |

Ning J, Yang G, Zhang Y, Geng D, Wang L, Liu X, Li Z, Yu H, Zhang J, Di X (2023) Smoke exposure levels prediction following laboratory combustion of Pinus koraiensis plantation surface fuel. Science of the Total Environment 881, 163402.
| Crossref | Google Scholar | PubMed |

Rothermel RC (1972) A mathematical model for predicting fire spread in wildland fuels. Research Paper INT-115. (USDA Forest Service, Intermountain Forest and Range Experiment Station)

Rothermel RC (1991) Predicting behavior and size of crown fires in the northern Rocky Mountains. Research Paper INT-438. (USDA Forest Service, Intermountain Research Station)

Rothermel RC, Anderson HE (1966) Fire spread characteristics determined in the laboratory. Research Paper INT-30. (USDA Forest Service, Intermountain Forest and Range Experiment Station)

Salvador R, Piñol J, Tarantola S, Pla E (2001) Global sensitivity analysis and scale effects of a fire propagation model used over Mediterranean shrublands. Ecological Modelling 136, 175-189.
| Crossref | Google Scholar |

Simard AJ (1968) The moisture content of forest fuels – 1. A review of the basic concepts. Information Report FF-X-14. (Canadian Department of Forest and Rural Development, Forest Fire Research Institute)

State Forestry Administration (2014) ‘Report on forest resources in China.’ (China Forestry Publishing House: Beijing)

Storey MA, Bedward M, Price OF, Bradstock RA, Sharples JJ (2021) Derivation of a Bayesian fire spread model using large-scale wildfire observations. Environmental Modelling & Software 144, 105127.
| Crossref | Google Scholar |

Sullivan AL (2009a) Wildland surface fire spread modelling, 1990–2007. 1: Physical and quasi-physical models. International Journal of Wildland Fire 18, 349-368.
| Crossref | Google Scholar |

Sullivan AL (2009b) Wildland surface fire spread modelling, 1990–2007. 2: Empirical and quasi-empirical models. International Journal of Wildland Fire 18, 369-386.
| Crossref | Google Scholar |

Thompson MP, Calkin DE (2011) Uncertainty and risk in wildland fire management: a review. Journal of Environmental Management 92, 1895-1909.
| Crossref | Google Scholar | PubMed |

Tihay V, Morandini F, Santoni PA, Perez-Ramirez Y, Barboni T (2012) Study of the influence of fuel load and slope on a fire spreading across a bed of pine needles by using oxygen consumption calorimetry. Journal of Physics. Conference Series 395, 012075.
| Crossref | Google Scholar |

Tihay V, Morandini F, Santoni PA, Perez-Ramirez Y, Barboni T (2014) Combustion of forest litters under slope conditions: burning rate, heat release rate, convective and radiant fractions for different loads. Combustion and Flame 161, 3237-3248.
| Crossref | Google Scholar |

Vaiciulyte S, Hulse LM, Veeraswamy A, Galea ER (2021) Cross-cultural comparison of behavioural itinerary actions and times in wildfire evacuations. Safety Science 135, 105122.
| Crossref | Google Scholar |

Weber RO (1991a) Modelling fire spread through fuel beds. Progress in Energy and Combustion Science 17, 67-82.
| Crossref | Google Scholar |

Weber RO (1991b) Toward a comprehensive wildfire spread model. International Journal of Wildland Fire 1, 245-248.
| Crossref | Google Scholar |

Xu X, Jia G, Zhang X, Riley WJ, Xue Y (2020) Climate regime shift and forest loss amplify fire in Amazonian forests. Global Change Biology 26, 5874-5885.
| Crossref | Google Scholar | PubMed |

Xue Q, Lin H, Wang F (2022) FCDM: an improved forest fire classification and detection model based on YOLOv5. Forests 13, 2129.
| Crossref | Google Scholar |

Yu P, Xu R, Abramson MJ, Li S, Guo Y (2020) Bushfires in Australia: a serious health emergency under climate change. The Lancet Planetary Health 4, e7-e8.
| Crossref | Google Scholar | PubMed |

Yuan X, Liu N, Xie X, Viegas DX (2020) Physical model of wildland fire spread: parametric uncertainty analysis. Combustion and Flame 217, 285-293.
| Crossref | Google Scholar |

Zhang Y, Sun P (2020) Study on the diurnal dynamic changes and prediction models of the moisture contents of two litters. Forests 11, 95.
| Crossref | Google Scholar |