TY - JOUR
T1 - Fire Responses Shape Plant Communities in a Minimal Model for Fire Ecosystems across the World
AU - Magnani, Marta
AU - Díaz-Sierra, Rubén
AU - Sweeney, Luke
AU - Provenzale, Antonello
AU - Baudena, Mara
N1 - Publisher Copyright:
© 2023 The University of Chicago. All rights reserved. Published by The University of Chicago Press.
PY - 2023/9
Y1 - 2023/9
N2 - Across plant communities worldwide, fire regimes re-flect a combination of climatic factors and plant characteristics. To shed new light on the complex relationships between plant characteristics and fire regimes, we developed a new conceptual mechanistic model that includes plant competition, stochastic fires, and fire-vegetation feedback. Considering a single standing plant functional type, we observed that highly flammable and slowly colonizing plants can persist only when they have a strong fire response, while fast colonizing and less flammable plants can display a larger range of fire re-sponses. At the community level, the fire response of the strongest competitor determines the existence of alternative ecological states (i.e., different plant communities) under the same environmental con-ditions. Specifically, when the strongest competitor had a very strong fire response, such as in Mediterranean forests, only one ecological state could be achieved. Conversely, when the strongest competitor was poorly fire adapted, alternative ecological states emerged—for ex-ample, between tropical humid savannas and forests or between different types of boreal forests. These findings underline the importance of including the plant fire response when modeling fire ecosystems, for example, to predict the vegetation response to invasive species or to climate change.
AB - Across plant communities worldwide, fire regimes re-flect a combination of climatic factors and plant characteristics. To shed new light on the complex relationships between plant characteristics and fire regimes, we developed a new conceptual mechanistic model that includes plant competition, stochastic fires, and fire-vegetation feedback. Considering a single standing plant functional type, we observed that highly flammable and slowly colonizing plants can persist only when they have a strong fire response, while fast colonizing and less flammable plants can display a larger range of fire re-sponses. At the community level, the fire response of the strongest competitor determines the existence of alternative ecological states (i.e., different plant communities) under the same environmental con-ditions. Specifically, when the strongest competitor had a very strong fire response, such as in Mediterranean forests, only one ecological state could be achieved. Conversely, when the strongest competitor was poorly fire adapted, alternative ecological states emerged—for ex-ample, between tropical humid savannas and forests or between different types of boreal forests. These findings underline the importance of including the plant fire response when modeling fire ecosystems, for example, to predict the vegetation response to invasive species or to climate change.
KW - alternative ecological states
KW - ecological modeling
KW - fires
KW - plant communities
KW - plant fire response
KW - plant traits
UR - http://www.scopus.com/inward/record.url?scp=85168443422&partnerID=8YFLogxK
U2 - 10.1086/725391
DO - 10.1086/725391
M3 - Article
C2 - 37606944
AN - SCOPUS:85168443422
SN - 0003-0147
VL - 202
SP - E83-E103
JO - American Naturalist
JF - American Naturalist
IS - 3
ER -