A Population Model of Chaparral Vegetation Response to Frequent Wildfires
The recent increase in wildfire frequency in the Santa Monica Mountains (SMM) may substantially impact plant community structure. Species of Chaparral shrubs represent the dominant vegetation type in the SMM. These species can be divided into three life history types according to their response to w...
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Veröffentlicht in: | Bulletin of mathematical biology 2013-12, Vol.75 (12), p.2324-2345 |
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Sprache: | eng |
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Zusammenfassung: | The recent increase in wildfire frequency in the Santa Monica Mountains (SMM) may substantially impact plant community structure. Species of Chaparral shrubs represent the dominant vegetation type in the SMM. These species can be divided into three life history types according to their response to wildfires. Nonsprouting species are completely killed by fire and reproduce by seeds that germinate in response to a fire cue, obligate sprouting species survive by resprouting from dormant buds in a root crown because their seeds are destroyed by fire, and facultative sprouting species recover after fire both by seeds and resprouts. Based on these assumptions, we developed a set of nonlinear difference equations to model each life history type. These models can be used to predict species survivorship under varying fire return intervals. For example, frequent fires can lead to localized extinction of nonsprouting species such as
Ceanothus megacarpus
while several facultative sprouting species such as
Ceanothus spinosus
and
Malosma (Rhus) laurina
will persist as documented by a longitudinal study in a biological preserve in the SMM. We estimated appropriate parameter values for several chaparral species using 25 years of data and explored parameter relationships that lead to equilibrium populations. We conclude by looking at the survival strategies of these three species of chaparral shrubs under varying fire return intervals and predict changes in plant community structure under fire intervals of short return. In particular, our model predicts that an average fire return interval of greater than 12 years is required for 50 % of the initial
Ceanothus megacarpus
population and 25 % of the initial
Ceanothus spinosus
population to survive. In contrast, we predict that the
Malosma laurina
population will have 90 % survivorship for an average fire return interval of at least 6 years. |
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ISSN: | 0092-8240 1522-9602 |
DOI: | 10.1007/s11538-013-9894-6 |