Register      Login
International Journal of Wildland Fire International Journal of Wildland Fire Society
Journal of the International Association of Wildland Fire
Shopping Cart: ( empty )
You are here: Home > Journals > WF > WF06109
RESEARCH ARTICLE
Contents Vol 16(4)

Spatial and temporal patterns of plant functional types under simulated fire regimes

Juli G. Pausas A C and F. Lloret B
+ Author Affiliations
- Author Affiliations

A CEAM (Fundación Centro de Estudios Ambientales del Mediterráneo), C/ Charles R. Darwin 14, Parc Tecnològic, 46980 Paterna, València, Spain & Departament d’Ecologia, Universitat d’Alacant, Apartat Correus 99, E-03080, Alacant, Spain.

B CREAF (Center for Ecological Research and Forestry Applications) and Unit of Ecology, Department of Animal and Plant Biology and Ecology, Autonomous University of Barcelona, E-08193 Bellaterra, Barcelona, Spain.

C Corresponding author. Email: juli@ceam.es, pausas@gmail.com

International Journal of Wildland Fire 16(4) 484-492 https://doi.org/10.1071/WF06109
Submitted: 13 July 2006  Accepted: 28 February 2007   Published: 20 August 2007

Abstract

In spite of enormous fire suppression advances in Mediterranean countries, large high-intensity fires are still common. The effects on vegetation structure and composition of fire and fire regime changes at large spatial and temporal scales are poorly known, and landscape simulation models may throw some light in this regard. Thus, we studied how the abundance, richness, and spatial distribution of the different plant types are sensitive to the frequency, extent and spatial distribution of wildfires, using a landscape simulation model (FATELAND). We simulated the dynamics of 10 plant functional types (PFTs) defined as combinations of post-fire persistence strategies and life forms, under the following fire scenarios: No Fire, Suppressed (one large fire every 20 years), Prescribed (small fuel reductions every year), Unmanaged-1 (two small fires every year) and Unmanaged-2 (four small fires every year). The results suggest that the different fire regimes generate different spatial fire-recurrence patterns and changes in the proportion of the dominant species. For instance, with increasing fire recurrence, seeder shrubs (i.e. those recruiting new individuals after fire from persisting seed bank) with early reproduction increased and seeder trees decreased, while little variation was found for resprouters. Fire also increased the spatial aggregation of plants, while PFT richness decreased with increasing fire recurrence. The results suggest patterns of changes similar to those reported in field studies, and thus they provide consistent hypotheses on the possible vegetation changes due to different fire scenarios.

Additional keywords: FATE model, landscape model, Mediterranean, resprouter, seeder, simulation, vegetation dynamics.


Acknowledgements

This work has been financed by the Spanish government’s SINREG project (REN2003–07198-C02–01 and 02/GLO). It also contributes to the European research group (GDRE) project ‘Mediterranean and mountain ecosystems in a changing world’, funded by Generalitat de Catalunya and CNRS. CEAM is supported by the Generalitat Valenciana and Bancaixa.


References


Baker WL (1994) Restoration of landscape structure altered by fire suppression. Conservation Biology  8, 763–769.
Crossref | GoogleScholarGoogle Scholar | Grove AT, Rackham O (2001) The nature of Mediterranean Europe: an ecological history. (Yale University Press: New Haven, CT)

Haydon DT, Friar JK , Pianka ER (2000) Fire-driven dynamic mosaic in the Great Victoria Desert, Australia. 1. Fire geometry. Landscape Ecology  15, 373–381.
Crossref | GoogleScholarGoogle Scholar | Huston MA (1994) Biological Diversity: The Coexistence of Species on Changing Landscapes. (Cambridge University Press: Cambridge)

Jacobson AL, Davis SD, Babritius SL (2004) Fire frequency impacts non-sprouting chaparral shrubs in the Santa Monica Mountains of southern California. In ‘Ecology, conservation and management of Mediterranean climate ecosystems’. (CD-ROM) (Eds M Arianoutsou, VP Panastasis) (Millpress: Rotterdam, Netherlands)

Keeley JE (1986) Resilience of Mediterranean shrub communities to fires. In ‘Resilience in Mediterranean-type ecosystems’. (Eds B Dell, AJM Hopkins, BB Lamont) pp. 95–112. (Dr. W. Junk Publisher: Dordrecht, Netherlands)

Keeley J (2006) Fire Management Impacts on Invasive Plants in the Western United States. Conservation Biology  20, 375–384.
Crossref | GoogleScholarGoogle Scholar | PubMed | Le Maitre DC, Midgley JJ (1992) Plant reproductive ecology. In ‘The ecology of Fynboss: nutrients, fire and diversity’. (Ed. RM Cowling) pp. 135–174. (Oxford University Press: Oxford)

Lloret F (1998) Fire, canopy and seedling dynamics in Mediterranean shrublands of Northeastern Spain. Journal of Vegetation Science  9, 417–430.
Crossref | GoogleScholarGoogle Scholar | Moreno JM, Vázquez A, Vélez R (1998) Recent history of forest fires in Spain. In ‘Large Forest Fires’. (Ed. JM Moreno) pp. 159–185. (Backhuys Publishers: Leiden, The Netherlands)

Ojeda F, Marañón T , Arroyo J (1996) Postfire regeneration of a Mediterranean heathland in Southern Spain. International Journal of Wildland Fire  6, 191–198.
Crossref | GoogleScholarGoogle Scholar | Papió C (1994) Ecologia del foc i regeneració en garrigues i pinedes mediterrànies. (Institut d’Estudis Catalans: Barcelona)

Pausas JG (1999) The response of plant functional types to changes in the fire regime in Mediterranean ecosystems. A simulation approach. Journal of Vegetation Science  10, 717–722.
Crossref | GoogleScholarGoogle Scholar | Pausas JG, Abdel Malak D (2004) Spatial and temporal patterns of fire and climate change in the eastern Iberian Peninsula (Mediterranean Basin). In ‘Ecology, Conservation and Management of Mediterranean Climate Ecosystems of the World’. MEDECOS 10th International Conference, Rhodes, Greece. (Eds M Arianoutsou, VP Papanastasis) (Millpress: Rotterdam, The Netherlands)

Pausas JG , Verdú M (2005) Plant persistence traits in fire-prone ecosystems of the Mediterranean basin: a phylogenetic approach. Oikos  109, 196–202.
Crossref | GoogleScholarGoogle Scholar | van Wilgen BW, Bond WJ, Richardson DM (1992) Ecosystem Management. In ‘The Ecology of fynbos. Nutrients, fire and diversity’. (Ed. R Cowling) pp. 345–371. (Oxford University Press: Cape Town)

Weir JMH , Johnson EA (2000) Fire frequency and the spatial age mosaic of the mixed-wood boreal forest in Western Canada. Ecological Applications  10, 1162–1177.
Zedler PH (1995a) Fire frequency in southern California shrublands: biological effects and management options. In ‘Brushfires in California: ecology and resource management’. (Eds JE Keeley, T Scott) pp. 101–112. (International Association of Wildland Fire: Fairfield, WA, USA)

Zedler PH (1995b) Plant life history and dynamic specialization in the chaparral/coastal sage shrub flora in southern California. In ‘Ecology and biogeography of Mediterranean ecosystems in Chile, California and Australia’. (Eds MTK Arroyo, PH Zedler, MD Fox) pp. 89–115. (Springer-Verlag: New York)

Zedler PH, Gautier CR , McMaster GS (1983) Vegetation change in response to extreme events: the effect of a short interval between fires in California chaparral and coastal sage scrub. Ecology  64, 809–818.
Crossref | GoogleScholarGoogle Scholar |