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Showing papers by "Stephen E. Williams published in 1998"


Journal ArticleDOI
TL;DR: Multivariate analyses of the ecological characteristics of frog species show that it is not a single characteristic that isolates those species that have declined from those which have not, and this has important implications for the determination of the causal factors in the unexplained global decline of many amphibian species.
Abstract: Rainforest frogs are classified into nine ecological guilds based on features of reproduction, habitat use, temporal activity, microhabitat and body size. The largest ecological differences are between the microhylid frogs and the rest of the frog species. Within the non-microhylids, there are two primary groups consisting of (i) regionally endemic rainforest specialists, and (ii) a more ecologically diverse group of species that are less specialized in their habitat requirements. Most of the regionally endemic rainforest specialists, which includes species in three ecological guilds, have declined or gone missing in recent years. Multivariate analyses of the ecological characteristics of these species show that it is not a single characteristic that isolates those species that have declined from those which have not. The guilds that have undergone significant population declines in the Wet Tropics are all characterized by the combination of low fecundity, a high degree of habitat specialization and reproduction in flowing streams. These results have important implications for the determination of the causal factors in the unexplained global decline of many amphibian species.

131 citations


Journal ArticleDOI
TL;DR: The effect of the change in vegetation structure from closed rain forest to tall open forest on the small mammal assemblage was studied by live trapping at three sites where the ecotone was very narrow (<20 m) near the southern end of the Wet Tropics World Heritage Area of Australia.
Abstract: The effect of the change in vegetation structure from closed rain forest to tall open forest on the small mammal assemblage was studied by live trapping at three sites where the ecotone was very narrow (<20 m) near the southern end of the Wet Tropics World Heritage Area of Australia. Habitat heterogeneity was significantly higher in the mixed open forest/ecotone area than in the adjacent rain forest. There was a large change in the structure of the small mammal assemblage coincident with the vegetation discontinuity. Although the species richness of small mammals was relatively constant across the gradient, the evenness and diversity of the assemblage declined across the transition from open forest into rain forest and biomass increased, largely due to the high abundance of Rattus fuscipes in the rain forest. The results suggest that the species richness of the small mammal assemblage was not determined by the spatial heterogeneity of the vegetation structure. The species composition of the rain forest is probably related to the historical biogeography of the area whereas the species richness of the wet sclerophyll forest is probably due to a mass-area effect from the adjacent large areas of rain forest and dry sclerophyll forest. However, the evenness, and therefore the diversity of the assemblage, was strongly affected by habitat heterogeneity.

42 citations


Dissertation
01 Jan 1998
TL;DR: The results suggest that habitat heterogeneity and patterns of localised extinctions (species sifting) during historical contractions of the rainforest have been extremely important processes in determining regional patterns of vertebrate biodiversity in Australia's wet tropical rainforests.
Abstract: This study examined the spatial patterns of vertebrate biodiversity, with an emphasis on mammals, in the Australian Wet Tropics biogeographic region over a range of spatial scales. Regional patterns of diversity were described on the basis of a review and collation of all available data on vertebrate distributions. The highest species diversity of vertebrates was found in sclerophyll habitats (approximately 388 species). Rainforest was considerably less species-rich with about 259 vertebrate species; however, regional endemism was much higher in rainforest (25%) than in the combined sclerophyll habitats (4%). Although there was no consistent latitudinal or altitudinal dine in diversity, there was a consistent turnover in the assemblage composition of vertebrates, both altitudinally and latitudinally. Habitat diversity at the landscape scale was consistently important in explaining the variance in patterns of species richness. The number of regionally endemic species of vertebrates and the proportion of regional endemics present in each sub-region were both related to the geographic shape and area of sub-regional patches of rainforest. Shape had a more significant influence on regional endemism than area, while area had a stronger influence on species richness. These patterns were similar for all terrestrial vertebrate classes. Mammal assemblages were examined in more detail: multivariate analyses suggested five different geographically separated rainforest mammal assemblages. The most diverse was found in the central uplands (Atherton Tableland) with a decrease in diversity to the north and south, and with decreasing altitude. The most diverse areas were characterised by large areas of rainforest with a rounder shape (low shape index), high annual rainfall, consistent rainfall in the dry season and a diversity of rainfall regimes. The combination of rainforest area and shape explained most of the variance (r2 = 0.74) in the patterns of species richness of rainforest mammals. Various measures of habitat diversity were also dependent on area, and a similar degree of the variance in species richness (r2 = 0.78) was explained by using rainforest shape and habitat diversity variables (rainfall and vegetation diversity) and excluding area. This suggests that the effect of area on the patterns of species richness was primarily due to its positive influence on habitat heterogeneity. Analysis of the mammalian guild structure indicated that it was the number of species within guilds that most strongly affected patterns of species richness, although the number of guilds also had an effect. Most of the variance in species richness could be attributed to three guilds: arboreal folivores, small scansorial and small scansorial folivore-omnivores. The results suggest that habitat heterogeneity and patterns of localised extinctions (species sifting) during historical contractions of the rainforest have been extremely important processes in determining regional patterns of vertebrate biodiversity in Australia's wet tropical rainforests. An investigation of the local-scale patterns of mammal diversity was undertaken on the southern Atherton Tableland Spotlighting and live trapping were used to examine the relationships between the composition of the mammal assemblage and habitat structure over several spatial scales. The results showed that the structure of the mammal assemblages was closely correlated with vegetation structure. The presence or absence of specific guilds was related to vegetation complexity, although total species richness was not. Local species richness of ground-dwelling mammals was mostly a product of the spatial variability in assemblage structure (b diversity), which was related to the spatial variability in vegetation structure. The effect of spatial scale is crucial to the understanding of the generality of processes which limit or promote biodiversity. Each spatial scale represents a nested hierarchy within the larger scales. The available species pool at a given spatial scale constrains the upper limit of species richness possible at the smaller scales while spatial patterns within a scale are determined by processes acting at that scale. This study examined patterns of diversity over a range of spatial scales and conceptual models are presented which describe the different spatial scales and the variety of processes which act at each spatial scale.

8 citations