Summary1. Life table response experiment (LTRE) analyses have been widely used to examine the sources of differences in the long-term deterministic growth rate (r = log k) of stage-structured populations that live in spatially distinct habitats or under distinct experimental conditions. However, existing methods for LTRE analysis ignore the fact that persistent temporal variation in matrix elements results in a long-term stochastic growth rate (a = log k s ) that is different from the deterministic growth rate (r) and thus do not take into account environmental stochasticity. 2. Here, we develop a stochastic extension of LTRE methods that can be used to compare stochastic growth rates among populations that differ in the observed variability of their matrix elements over time. We illustrate our method with actual data and explore a range of questions that may be addressed with these new tools. Specifically, we investigate how variability in weather conditions affected the population dynamics of the short-lived perennial plant species Anthyllis vulneraria and examine how differences in stochastic growth rates (a) are determined by contributions of mean matrix elements and variability in matrix elements. 3. We find that, consistent with the life history of the species, differences in mean fertility and growth made the largest contribution to differences in a, whereas in terms of variability fertility made the largest contribution in most populations. However, we also find that in all populations, the magnitude of the total contribution of mean matrix elements outweighed that of variability. Finally, increasing soil depth significantly lowered contributions of variability in matrix elements, but it was not related to contributions of differences in mean matrix elements. 4. Synthesis. Stochastic life table response experiment analysis described here provides the first systematic way of incorporating observed differences in temporal variability into the comparison of natural populations. A key finding from this study is that populations occurring on relatively deeper soils were better buffered against climatic variation than populations occurring on shallow soils. We expect this new approach to analyse temporal variability to prove especially useful in the analysis of natural populations experiencing environmental change.
M. 2004. Population structure and adult plant performance of forest herbs in three contrasting habitats. Á/ Ecography 27: 225 Á/241.In Flanders, forests have been subjected to subsequent periods of reclamation and reforestation, leading to a mosaic of forest patches of various ages and with different abiotic conditions, depending on the duration and intensity of the past agricultural activities. While extensive research has been done on the relative importance of dispersal limitation and establishment limitation in explaining colonization patterns of so-called ancient forest plant species, little is known about the viability of populations of these species once they have colonized recent forests. Therefore, a comparative study on population structure and plant performance was carried out for three forest plant species with different colonization capacity (Primula elatior, Geum urbanum and Arum maculatum ) in three different habitat types: ancient forests, recently established forests and small landscape elements (hedgerows). Contrary to the expectation, it was shown that adult plant performance Á/ a combination of vegetative as well as reproductive characteristics Á/ of the three species was generally higher in recent forests and small landscape elements. This also led to higher seedling densities and proportions in these habitat types. Adult densities, however, were extremely low in newly established forests, suggesting reduced seedling and juvenile survival under these circumstances, probably due to higher light availability and hence increased competition from species like Urtica dioica . Although there might be no immediate establishment limitation, installing a shrub layer in recent forests might enhance survival and result in a stable population structure. Hedgerows on the other hand seemed to contain viable populations of certain forest plant species and can therefore function as an important colonization source when incorporated in recently established forests. P. Endels
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