Browsing by Subject "seed dispersal"

I examined recruitment patterns of multiple tree species in a western Amazonian floodplain forest at three ontogenetic stages: seed fall, seedling establishment, and sapling recruitment.

From analyzing a long-term seed rain dataset collected using a high-density array of seed traps, I confirmed that seed fall decreases sharply with increasing distance from fruiting trees, with disproportionately large contributions from a very small fraction of all trees. Patterns of seed fall, although idiosyncratic for individual species, tended to relate to dispersal syndrome. Intact seeds were found at significantly greater distances away from fruiting adults than ripe fruit and almost exclusively comprised the tail of the seed shadow for most species.

Saplings of all species examined recruited in areas of very low predicted seed density at significantly higher abundances than expected under a null hypothesis of "all seeds are equal". The value of a seed in terms of its potential to produce a sapling recruit - measured as sapling/seed ratio - initially increased greatly with increasing distance from reproductive conspecific adults and leveled off at farther distances, in almost all species.

A parallel experimental study employed >1000 individual seedlings of common tree species situated near and far from conspecific adults. Overall survival for all species pooled and for eight out of 11 individual species was significantly higher at sites located far from versus close to conspecific adults, with the study design controlling for seedling density at sites. Survival analysis based on multiple censuses revealed that a "distance effect" persisted and intensified over time, although the timing of onset of distance-related differential mortality differed amongst species. The role of host-specific invertebrate herbivores and microbial pathogens in causing seedling mortality near conspecific adults was confirmed by the use of mesh exclosures.

Overall, my results provide community-level support for the influence of distance-dependent processes on recruitment patterns. Seed dispersal appears critical for successful recruitment and undispersed seeds make a minimal contribution. When de-coupled from distance-dependence, effects of competition-based density-dependent processes on recruitment were weak or undetectable. I conclude that community-level tree recruitment processes and patterns in western Amazonian lowland rainforests that harbor intact floral and faunal assemblages conform closely to predictions of the Janzen-Connell hypothesis of tropical tree recruitment.

Drylands, comprising arid and semi-arid areas and the dry subtropics, over some 40% of the world's land area and support approximately 2 billion people, including at least 1 billion who depend on dryland agriculture and grazing. 10-20% of drylands are estimated to have already undergone degradation or desertification, and lack of monitoring and assessment remains a key impediment to preventing further desertification. Change in vegetation cover, specifically in the spatial organization of vegetation may occur prior to irreversible land degradation, and can be used to assess desertification risk. Coherent spatial structures arise in the distribution of dryland vegetation where plant growth is localized in regular spatial patterns. Such "patterned vegetation" occurs across a variety of vegetation and soil types, extends over at least 18 million ha, occurs in 5 continents and is economically and environmentally valuable in its own right.

Vegetation patterning in drylands arises due to positive feedbacks between hydrological forcing and plant growth so that the patterns change in response to trends in mean annual rainfall. Mathematical models indicate that vegetation patterns collapse to a desertified state after undergoing a characteristic set of transformations so that the condition of a pattern at any point in time can be explicitly linked to ecosystem health. This dissertation focuses on the mathematical description of vegetation patterns with a view to improving such predictions. It evaluates the validity of current mathematical descriptions of patterning for the specific case of small-scale vegetation patterns and proposes alternative hypotheses for their formation. It assesses the significance of seed dispersal in determining pattern form and dynamics for two cases: vegetation growing on flat ground with isotropic patterning, and vegetation growing on slopes and having anisotropic (i.e. directional) patterning. Thirdly, the feedbacks between local biomass density and infiltration capacity, one of the positive feedbacks believed to contribute to patterning, are quantified across a wide range of soil and climatic conditions, and new mathematical descriptions of the biomass-infiltration relationship are proposed. Finally the influence of land surface microtopography on the partitioning of rainfall into infiltration and runoff is assessed.