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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

Prediction of fire occurrence from live fuel moisture content measurements in a Mediterranean ecosystem

Emilio Chuvieco A B , Isabel González A , Felipe Verdú A , Inmaculada Aguado A and Marta Yebra A
+ Author Affiliations
- Author Affiliations

A Department of Geography, University of Alcalá, E-28801 Alcalá de Henares, Spain.

B Corresponding author. Email: emilio.chuvieco@uah.es

International Journal of Wildland Fire 18(4) 430-441 https://doi.org/10.1071/WF08020
Submitted: 5 February 2008  Accepted: 22 July 2008   Published: 29 June 2009

Abstract

The present paper presents and discusses the relationships between live Fuel Moisture Content (FMC) measurements and fire occurrence (number of fires and burned area) in a Mediterranean area of central Spain. Grasslands and four shrub species (Cistus ladanifer L., Rosmarinus officinalis L., Erica australis L. and Phillyrea angustifolia L.) were sampled in the field from the spring to the summer season over a 9-year period. Higher seasonal FMC variability was found for the herbaceous species than for shrubs, as grasslands have very low values in summertime. Moisture variations of grasslands were found to be good predictors of number of fires and total burned surface, while moisture variation of two shrubs (C. ladanifer L. and R. officinalis L.) was more sensitive to both the total burned area and the occurrence of large fires. All these species showed significant differences between the FMC of high and low occurrence periods. Three different logistic regression models were built for the 202 periods of analysis: one to predict periods with more and less than seven fires, another to predict periods with and without large fires (>500 ha), and the third to predict periods with more and less than 200 ha burned. The results showed accuracy in predicting periods with a high number of fires (94%), and extensive burned area (85%), with less accuracy in estimating periods with large fires (58%). Finally, empirical functions based on logistic regression analysis were successfully related to fire ignition or potential burned area from FMC data. These models should be useful to integrate FMC measurements with other variables of fire danger (ignition causes, for instance), to provide a more comprehensive assessment of fire danger conditions.

Additional keywords: fire danger, fire risk.


Acknowledgements

We sincerely thank the administration authorities of the Cabañeros National Park for their support in accessing the field plots and cooperation throughout the project.


References


Almendros G, González-Vila FJ , Martin F (1990) Fire-induced transformation of soil organic matter from an oak forest: an experimental approach to the effects of fire on humic substances. Soil Science  149, 158–168.

CAS | | Crossref | Chuvieco E, Allgöwer B, Salas FJ (2003b) Integration of physical and human factors in fire danger assessment. In ‘Wildland Fire Danger Estimation and Mapping. The Role of Remote Sensing Data’. (Ed. E Chuvieco) pp. 197–218. (World Scientific Publishing: Singapore)

Chuvieco E, Aguado I , Dimitrakopoulos A (2004a) Conversion of fuel moisture content values to ignition potential for integrated fire danger assessment. Canadian Journal of Forest Research-Revue Canadienne de Recherche Forestiere  34(11), 2284–2293.
Crossref | GoogleScholarGoogle Scholar | Deeming JE, Lancaster JW, Fosberg MA, Furman RW, Schroeder MJ (1974) The National Fire-Danger Rating System. USDA Forest Service, Rocky Mountain Forest and Range Experiment Station, Research Paper RM-84. (Fort Collins, CO)

Deeming JE, Burgan RE, Cohen JD (1978) The National Fire-Danger Rating System – 1978. USDA Forest Service, Intermountain Forest and Range Experiment Station, General Technical Report GTR INT-39. (Ogden, UT)

Dimitrakopoulos A , Papaioannou KK (2001) Flammability assessment of Mediterranean forest fuels. Fire Technology  37, 143–152.
Crossref | GoogleScholarGoogle Scholar | Nelson RM (2001) Water relations of forest fuels. In ‘Forest Fires: Behavior and Ecological Effects’. (Eds EA Johnson, K Miyanishi) pp. 79–149. (Academic Press: San Diego, CA)

Nunes MCS, Vasconcelos MJ, Pereira JMC, Dasgupta N , Alldredge RJ (2005) Land cover type and fire in Portugal: do fires burn landcover selectively? Landscape Ecology  20, 661–673.
Crossref | GoogleScholarGoogle Scholar | Pausas JG, Vallejo VR (1999) The role of fire in European Mediterranean ecosystems. In ‘Remote Sensing of Large Wildfires in the European Mediterranean Basin’. (Ed. E Chuvieco) pp. 3–16. (Springer-Verlag: Berlin)

Ray D, Nepstad D , Moutinho P (2005) Micrometeorological and canopy controls of fire susceptibility in a forested Amazon landscape. Ecological Applications  15, 1664–1678.
Crossref | GoogleScholarGoogle Scholar | San Miguel-Ayanz J, Carlson JD, Alexander M, Tolhurst K, Morgan G, Sneeuwjagt R, Dudley M (2003) Current methods to assess fire danger potential. In ‘Wildland Fire Danger Estimation and Mapping. The Role of Remote Sensing Data’. (Ed. E Chuvieco) pp. 21–61. (World Scientific Publishing: Singapore)

Slavik B (1974) ‘Methods for Studying Plant Water Relations.’ (Czechoslovak Academy of Sciences and Springer Verlag: Prague)

Stocks BJ, Mason JA, Todd JB, Bosch EM, Wotton BM, Amiro BD, Flannigan MD, Hirsch KG, Logan KA, Martell DL , Skinner WR (2003) Large forest fires in Canada, 1959–1997. Journal of Geophysical Research – Atmospheres  108, 8149.
Crossref | GoogleScholarGoogle Scholar | Van Wagner CE (1974) Structure of the Canadian Forest Fire Weather Index. Canadian Department of Environment. Canadian Forestry Service, Publication 1333. (Ottawa, ON)

Vasconcelos MJP, Silva S, Tomé M, Alvim M , Pereira JMC (2001) Spatial prediction of fire ignition probabilities: comparing logistic regression and neural networks. Photogrammetric Engineering and Remote Sensing  67, 73–83.
Viegas DX (1998) Fuel moisture evaluation for fire behaviour assessment. In ‘Advanced Study Course on Wildfire Management. Final Report’. (Eds G Eftichidis, P Balabanis, A Ghazi) pp. 81–92. (European Commission: Marathon, Greece)

Viegas DX, Viegas TP , Ferreira AD (1992) Moisture content of fine forest fuels and fire occurrence in central Portugal. International Journal of Wildland Fire  2, 69–85.
Crossref | GoogleScholarGoogle Scholar | Visauta B (1998) ‘Análisis Estadístico con SPSS para Windows. Volumen I. Estadística Básica.’ (McGraw Hill: Madrid)

Yebra M, Chuvieco E , Riaño D (2008) Estimation of live Fuel Moisture Content from MODIS images for fire risk assessment. Agricultural and Forest Meteorology  148, 523–536.
Crossref | GoogleScholarGoogle Scholar |