: This study aims to identify and characterize the spatial and temporal evolution of the types of vegetation that are most affected by forest fires in Europe. Alguns conceitos básicos sobre os fogos rurais em Portugal. Cambridge University Press, Cambridge, United Kingdom and New York, NY, USA. Atmospheric conditions associated with the exceptional fire season of 2003 in Portugal. In: Incêndios Florestais em Portugal–Caracterização, Impactes e Prevenção. The characterization of the fuels is an important issue of the fire regime in each specific ecosystem while, on the other hand, fire is an important disturbance for global vegetation dynamics.: Corine Land Cover maps for 20 (CLC2000, CLC2006) and burned area (BA) perimeters, from 2000 to 2013 in Europe are combined to access the spatial and temporal evolution of the types of vegetation that are most affected by wild fires using descriptive statistics and Geographical Information System (GIS) techniques.: The spatial and temporal distribution of BA perimeters, vegetation and burnt vegetation by wild fires was performed and different statistics were obtained for Mediterranean and entire Europe, confirming the usefulness of the proposed land cover system. Incêndios Florestais em Portugal: Caracterização, Impactes e Prevenção, pp: 133-161. The history and characteristics of the 1980-2005 Portuguese rural fire database. International Journal of Climatology 26: 1741-1757. Trigo RM, Sousa PM, Pereira MG, Rasilla D, Gouveia CM, 2013.
Amraoui M, Liberato ML, Calado TJ, Da Camara CC, Coelho LP, Trigo RM, et al., 2013. Technical and methodological guide for updating CORINE Land Cover Database. Selective burning of forest vegetation in Canton Ticino (southern Switzerland). In: Incêndios Florestais em Portugal–Caracterização, Impactes e Prevenção. Physics and Chemistry of the Earth, Parts A/B/C 35: 553-560. Do Land Cover Changes Shape Sensitivity to Forest Fires in peri-urban Areas? Agenzia nazionale per le nueve tecnologie, l'energia e lo sviluppo economico sostenibile 1: 58-65. Natural disturbances in the European forests in the 19th and 20th centuries. Schmuck G, San-Miguel-Ayanz J, Camia A, Durrant T, Santos de Oliveira S, Boca R, et al., 2011.
Fire activity over Mediterranean Europe based on information from Meteosat-8. Joint Research Centre, European Commission, Luxembourg.
The differences between northern Europe and southern Europe and among the Mediterranean region in what concerns to vegetation cover, fire incidence, area burnt in land cover classes and fire proneness between classes for the different countries. Defining pyromes and global syndromes of fire regimes. Wildfire selectivity for land cover type: does size matter? Bengtsson J, Nilsson SG, Franc A, Menozzi P, 2000. Climatic and weather factors affecting fire occurrence and behavior. Annual Review of Environment and Resources 38: 57-80. Effects of regional climate change on rural fires in Portugal. Pereira MG, Trigo RM, da Camara CC, Pereira J, Leite SM, 2005. Qin D, Manning M, Chen Z, Marquis M, Averyt K, Tignor M, et al., 2007. Cambridge University Press, Cambridge, UK, New York, NY, USA. Rasilla DF, García-Codron JC, Carracedo V, Diego C, 2010.
Keywords: Fire proneness; Mixed forests; Land cover/land use; Fire regime; Europe; GIS; Corine land cover. Proceedings of the National Academy of Sciences 110: 6442-6447. Evidence of selective burning in Sardinia (Italy): which land-cover classes do wildfires prefer? Biodiversity, disturbances, ecosystem function and management of European forests. Büttner G, Feranec J, Jaffrain G, Mari L, Maucha G, Soukup T, 2004. Synoptic patterns associated with large summer forest fires in Portugal. Pezzatti G, Bajocco S, Torriani D, Conedera M, 2009. Fogo no jardim: compreensão do contexto dos incêndios em Portugal. Circulation patterns, wildfire risk and wildfire occurrence at continental Spain. Mediterranean forest research: challenges and opportunities in a changing environment.
Pereira JMC, Carreiras JMB, Silva JMN, Vasconcelos MJ, 2006. Solomon S, Qin D, Manning M, Chen Z, Marquis M, Averyt K, et al., 2007. Contribution of Working Group I to the Fourth Assessment Report of the Intergovernmental Panel on Climate Change. Daytime urban heat islands from Landsat ETM+ and Corine land cover data: An application to major cities in Greece. Trigo RM, Pereira J, Pereira MG, Mota B, Calado TJ, Dacamara CC, et al., 2006.
Hydrology and earth system sciences discussions 4: 439-473. Long‐term interactions between Mediterranean climate, vegetation and fire regime at Lago di Massaciuccoli (Tuscany, Italy). International Journal of Wildland Fire 23: 620-630. Updated world map of the Köppen-Geiger climate classification. Moisture content of fine forest fuels and fire occurrence in central Portugal. Global Forest Resources Assessment 2010 Main Report. Assessment of fire selectivity in relation to land cover and topography: a comparison between southern European countries. Consistent geographical patterns of changes in high-impact European heatwaves. Climate change impacts, adaptive capacity, and vulnerability of European forest ecosystems. Landscape–wildfire interactions in southern Europe: implications for landscape management. International Journal of Wildland Fire 20: 678-689.A fire proneness index is proposed to assess the fire selectivity of land cover classes. Natural Hazards & Earth System Sciences 11: 3343-3358. Modelling wildfire activity in Iberia with different atmospheric circulation weather types. The index allowed to quantify and to compare the propensity of vegetation classes and countries to fire.: The usefulness and efficiency of the land cover classification scheme and fire proneness index. Archibald S, Lehmann CE, Gómez-Dans JL, Bradstock RA, 2013. Pyrogeography and the global quest for sustainable fire management. Land use and topography influences on wildfire occurrence in northern Portugal. Pereira MG, Calado TJ, Da Camara CC, Calheiros T, 2013.