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RESEARCH ARTICLE
Contents Vol 17(2)

The meteorological conditions associated with extreme fire risk in Italy and Greece: relevance to climate model studies

P. Good A B D , M. Moriondo C , C. Giannakopoulos A and M. Bindi C
+ Author Affiliations
- Author Affiliations

A Institute for Environmental Research and Sustainable Development, National Observatory of Athens, P. Pendeli, 15236 Athens, Greece.

B Present address: Met Office Hadley Centre, FitzRoy Road, Exeter, EX1 3PB, UK.

C Department of Agronomy and Land Management, University of Florence, Italy.

D Corresponding author. Email: peter.good@metoffice.gov.uk

International Journal of Wildland Fire 17(2) 155-165 https://doi.org/10.1071/WF07001
Submitted: 18 December 2006  Accepted: 27 August 2007   Published: 18 April 2008

Abstract

The meteorological conditions associated with elevated and extreme long- and short-timescale forest fire risk are investigated by validating and diagnosing the Canadian Fire Weather Index (FWI) in the context of Tuscany in Italy, and Thessaloniki, Athens and Heraklion in Greece. The aim is to provide information to assist diagnosing experiments that use output from climate models to calculate FWI values. Links are made from fire risk to the widely used FWI, and then to the underlying meteorology, complementing other more complex fire risk model studies. First, the information about Mediterranean fire risk provided by the FWI is assessed by comparing the observed number of fires per day with FWI values based on the locally observed meteorology. This shows that the FWI provides some relatively consistent information for different locations, and suggests useful FWI thresholds indicating elevated and extreme fire risk. Then, the FWI system is split according to contributions from long- and short-timescale components, in a different way than usually adopted in the literature. Using the FWI thresholds suggested above, the long- and short-timescale meteorological conditions causing elevated and extreme FWI values are diagnosed. The results may help studies that investigate what aspects of projected climate change drive changes in fire weather risk, compare fire risk calculations from different climate models, or assess how climate models can be improved to provide better fire risk projections.

Additional keywords: climate change projections, extremes, impacts, simulations, wildfire.


Acknowledgements

The present work was supported by the European Commission 6th Framework project ENSEMBLES under contract number GOCE-CT-2003–505539 (www.ensembles-eu.org, accessed October 2007).


References


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Crossref | GoogleScholarGoogle Scholar | and inverting the result gives:

E5

At equilibrium in persistent dry conditions, combination of Van Wagner’s eqns 9 and 33–35 give:

E6

where w is windspeed (km h–1) and Ed is given by:

E7

where H is relative humidity (%) and T0 is a reference temperature. Ed is insensitive to temperature under the specified conditions, so it is sufficient to use a representative constant value T0 = 30°C in Eqn 7.

We are interested in the threshold FWI = 45, under conditions of fD > 35. Further, the expression for fD saturates at fD = 40. Therefore, we set FWI = 45 and fD = 40 in Eqn 5. This may be combined with Eqn 6 and solved for w, giving the following expression for windspeed as a function of Ed (and hence of relative humidity):

E8