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References

  • Alessio GA, Peñuelas J, Llusià J, Ogaya R, Estiarte M, De Lillis M. 2008. Influence of water and terpenes on flammability in some dominant Mediterranean species. International Journal of Wildland Fire 17: 274286.
  • Baeza J, Santana VM, Pausas JG, Vallejo R. 2011. Successional trends in standing dead biomass in Mediterranean basin species. Journal of Vegetation Science 22: 467474.
  • Baeza MJ, Raventós J, Escarré A, Vallejo VR. 2006. Fire risk and vegetation structural dynamics in Mediterranean shrubland. Plant Ecology 187: 189201.
  • Baeza MJ, Vallejo VR. 2006. Ecological mechanisms involved in dormancy breakage in Ulex parviflorus seeds. Plant Ecology 183: 191205.
  • Belcher CM, Mander L, Rein G, Jervis FX, Haworth M, Hesselbo SP, Glasspool IJ, McElwain JC. 2010. Increased fire activity at the Triassic/Jurassic boundary in Greenland due to climate-driven floral change. Nature Geoscience 3: 426429.
  • Bond WJ, Midgley JJ. 1995. Kill thy neighbour: an individualistic argument for the evolution of flammability. Oikos 73: 7985.
  • Bond WJ, Roux D, Erntzen R. 1990. Fire intensity and regeneration of myrmecochorous Proteaceae. South African Journal of Botany 56: 326330.
  • Bond WJ, Scott AC. 2010. Fire and the spread of flowering plants in the Cretaceous. New Phytologist 188: 11371150.
  • Bond WJ, Van Wilgen BW. 1996. Fire and plants. London, UK: Chapman & Hall.
  • Bowman DMJS, Balch JK, Artaxo P, Bond WJ, Carlson JM, Cochrane MA, D’Antonio CM, DeFries RS, Doyle JC, Harrison SP et al. 2009. Fire in the earth system. Science 324: 481484.
  • Bradstock RA, Auld TD. 1995. Soil temperature during experimental bushfire in relation to fire intensity: consequences for legume germination and fire management in south-eastern Australia. Journal of Applied Ecology 32: 7684.
  • Christensen NL. 1985. Shrubland fire regimes and evolutionary consequences. In: Pickett STA, White PS, eds. The ecology of natural disturbance and patch dynamics. Orlando, FL, USA: Academic Press, Inc, 85100.
  • Cornelissen JHC, Lavorel S, Garnier E, Díaz S, Buchmann N, Gurvich DE, Reich PB, Ter Steege H, Morgan HD, van der Heijden MGA et al. 2003. Handbook of protocols for standardised and easy measurement of plant functional traits worldwide. Australian Journal of Botany 51: 335380.
  • Cowan P, Ackerly D. 2010. Post-fire regeneration strategies and flammability traits of California chaparral shrubs. International Journal of Wildland Fire 19: 984989.
  • Dimitrakopoulos AP, Panov PI. 2001. Pyric properties of some dominant Mediterranean vegetation species. International Journal of Wildland Fire 10: 2327.
  • Endler JA. 1986. Natural selection in the wild. Princeton, NJ, USA: Princeton University Press.
  • Falconer DS. 1981. Introduction to quantitative genetics. London, New York: Longman.
  • Gill AM, Trollope WSW, MacArthur DA. 1978. Role of moisture in the flammability of natural fuels in the laboratory. Australian Forest Research 9: 199208.
  • He T, Lamont BB, Downes KS. 2011. Banksia born to burn. New Phytologist 191: 184196.
  • Keeley JE, Pausas JG, Rundel PW, Bond WJ, Bradstock RA. 2011. Fire as an evolutionary pressure shaping plant traits. Trends in Plant Science 16: 406411.
  • Keeley JE, Pfaff AH, Safford HD. 2005. Fire suppression impacts on postfire recovery of Sierra Nevada chaparral shrublands. International Journal of Wildland Fire 14: 255265.
  • Keeley JE, Zedler PH. 1998. Evolution of life histories in Pinus. In: Richardson DM, ed. Ecology and biogeography of Pinus. Cambridge, UK: Cambridge University Press, 219250.
  • Kerr B, Schwilk DW, Bergman A, Feldman MW. 1999. Rekindling an old flame: a haploid model for the evolution and impact of flammability in resprouting plants. Evolutionary Ecology Research 1: 807833.
  • Knox KJE, Clarke PJ. 2006. Fire season and intensity affect shrub recruitment in temperate sclerophyllous woodlands. Oecologia 149: 730739.
  • Midgley J, Bond W. 2011. Pushing back in time: the role of fire in plant evolution. New Phytologist 191: 57.
  • Moreira B, Tormo J, Estrelles E, Pausas JG. 2010. Disentangling the role of heat and smoke as germination cues in Mediterranean basin flora. Annals of Botany 105: 627635.
  • Moreno JM, Oechel WC. 1991. Fire intensity effects on germination of shrubs and herbs in southern California chaparral. Ecology 7: 19932004.
  • Mutch RW. 1970. Wildland fires and ecosystems – a hypothesis. Ecology 51: 10461051.
  • Ojeda F, Pausas JG, Verdú M. 2010. Soil shapes community structure through fire. Oecologia 163: 729735.
  • Papió C, Trabaud L. 1990. Structural characteristics of fuel components of five Mediterranean shrubs. Forest Ecology and Management 35: 249259.
  • Papió C, Trabaud L. 1991. Comparative study of the aerial structure of five shrubs of Mediterranean shrublands. Forest Science 37: 146159.
  • Paula S, Arianoutsou M, Kazanis D, Tavsanoglu Ç, Lloret F, Buhk C, Ojeda F, Luna B, Moreno JM, Rodrigo A et al. 2009. Fire-related traits for plant species of the Mediterranean basin. Ecology 90: 1420.
  • Pausas JG, Bradstock RA, Keith DA, Keeley JE, GCTE Fire Network. 2004. Plant functional traits in relation to fire in crown-fire ecosystems. Ecology 85: 10851100.
  • Pausas JG, Keeley JE. 2009. A burning story: the role of fire in the history of life. BioScience 59: 593601.
  • Pausas JG, Verdú M. 2008. Fire reduces morphospace occupation in plant communities. Ecology 89: 21812186.
  • Philpot CW. 1970. Influence of mineral content on the pyrolysis of plant materials. Forest Science 16: 461471.
  • Plucinski MP, Anderson WR. 2008. Laboratory determination of factors influencing successful point ignition in the litter layer of shrubland vegetation. International Journal of Wildland Fire 17: 628637.
  • Rundel P. 1981. Structural and chemical components of flammability. Fire regimes and ecosystem properties. Washington, DC, USA: US Forest Service General Technical Report WO-26, 183207.
  • Santana VM, Baeza MJ, Vallejo VR. 2011. Fuel structural traits modulating soil temperatures in different species patches of Mediterranean Basin shrublands. International Journal of Wildland Fire 20: 668677.
  • Saura-Mas S, Paula S, Pausas JG, Lloret F. 2010. Fuel loading and flammability in the Mediterranean basin woody species with different post-fire regenerative strategies. International Journal of Wildland Fire 19: 783794.
  • Schwilk DW. 2003. Flammability is a niche-construction trait: canopy architecture affects fire intensity. American Naturalist 162: 725733.
  • Schwilk DW, Ackerly DD. 2001. Flammability and serotiny as strategies: correlated evolution in pines. Oikos 94: 326336.
  • Schwilk DW, Kerr B. 2002. Genetic niche-hiking: an alternative explanation for the evolution of flammability. Oikos 99: 431442.
  • Snyder JR. 1984. The role of fire: mutch ado about nothing? Oikos 43: 404405.
  • Troumbis AY, Trabaud L. 1989. Some questions about flammability in fire ecology. Acta Oecologica 10: 167175.
  • Verdú M, Pausas JG. 2007. Fire drives phylogenetic clustering in Mediterranean basin woody plant communities. Journal of Ecology 95: 13161323.
  • Verdú M, Pausas JG, Segarra-Moragues JG, Ojeda F. 2007. Burning phylogenies: fire, molecular evolutionary rates, and diversification. Evolution 61: 21952204.
  • van Wilgen BW, Higgins KB, Bellstedt DU. 1990. The role of vegetation structure and fuel chemistry in excluding fire from forest patches in the fire-prone fynbos shrublands of South Africa. Journal of Ecology 78: 210222.
  • Zedler PH. 1995. Are some plants born to burn? Trends in Ecology and Evolution 10: 393395.