ORCID Profile
0000-0002-9664-9212
Current Organisation
University of Tasmania
Does something not look right? The information on this page has been harvested from data sources that may not be up to date. We continue to work with information providers to improve coverage and quality. To report an issue, use the Feedback Form.
Publisher: Wiley
Date: 12-07-2021
DOI: 10.1111/REC.13470
Abstract: Habitat loss is a primary cause of population decline for 85% of species recognized as threatened by the International Union for Conservation of Nature. Ecological restoration can mitigate and reverse the effects of habitat loss on wildlife, but many restoration programs lack a systematic approach to monitoring outcomes, if indeed restoration sites are monitored at all. Here, we evaluate the response of wildlife to restoration plantings in an agricultural landscape in Tasmania, Australia, five years after their establishment. We surveyed three faunal groups—ground‐dwelling invertebrates, birds and terrestrial mammals—and compared community composition in plantings with those of nearby livestock pasture and remnant woodlands. Habitat type had some influence on invertebrate communities with more pollinators, but fewer nectivores (predominantly Lepidoptera) and engulf predators in riparian plantings than in paddocks. In comparison, nonriparian plantings had more nectivores and pollinators and a greater proportion of small‐bodied invertebrates than in paddocks. Invertebrate biomass was positively associated with the presence of large ground‐foraging birds. Habitat type had a significant effect on the composition of bird communities in nonriparian areas, with small native species more abundant in plantings than in paddocks. Endangered mammal species were recorded using planting sites, including eastern bettongs and spotted‐tailed quolls. We describe possible trajectories to inform adaptive management of local restoration efforts. Our study provides a rare ex le that considers the response of multiple faunal groups to restoration concurrently and highlights differences in wildlife communities between restoring and reference habitats that are likely to impact ecosystem services.
Publisher: Wiley
Date: 12-2021
DOI: 10.1111/EMR.12504
Abstract: Temperate woodlands are amongst the most threatened ecosystems in Australia because the land on which they occur is highly suited to agriculture. Two hundred years of habitat loss and fragmentation in the Midlands agricultural region in Tasmania have led to widespread declines in native vertebrates and landscapes with populations of predators including feral Cat ( Felis catus ) and the native‐invasive Noisy Miner ( Manorina melanocephala ). Ecologists at the University of Tasmania co‐designed mechanistic animal‐centric research on mammals and birds in the Midlands to inform vegetation restoration carried out by Greening Australia that would support the recovery of wildlife species. We used species‐appropriate technologies to assess the decisions made by in idual animals to find food and shelter and to disperse across this fragmented landscape, and linked these, together with patterns of occupancy, across multiple spatial and temporal scales. We focussed on a native (Spotted‐tailed Quoll, Dasyurus maculatus ) and an invasive (feral Cat, Felis catus ) carnivore, a woodland‐specialist herbivore (Eastern Bettong, Bettongia gaimardi ) and woodland birds including the native‐invasive Noisy Miner. Our results, which show intense predatory and competitive pressure of cats and populations of Noisy Miner on native fauna, highlight how grounding restoration in the context of ecological interactions is essential to success in managing the impacts of invasive species in restored landscapes. Successful restoration will require innovative approaches in plantings and field experimentation with artificial refuges, to reduce habitat suitability for the Noisy Miner and cats and provide refuges for native mammals and birds to live in the landscape where cats also occur. Our results emphasise the significance of structural complexity of restoration plantings for supporting the recolonisation and persistence of native fauna. At large landscape‐scale, we demonstrate the importance of retaining small habitat elements, including ancient paddock trees, pivot irrigation corners and small, degraded remnants, in facilitating occupancy and dispersal and, therefore, persistence of wild animals across this agricultural region.
Publisher: Oxford University Press (OUP)
Date: 22-07-2023
Abstract: Forest disturbance has well-characterized effects on soil microbial communities in tropical and northern hemisphere ecosystems, but little is known regarding effects of disturbance in temperate forests of the southern hemisphere. To address this question, we collected soils from intact and degraded Eucalyptus forests along an east–west transect across Tasmania, Australia, and characterized prokaryotic and fungal communities using licon sequencing. Forest degradation altered soil microbial community composition and function, with consistent patterns across soil horizons and regions of Tasmania. Responses of prokaryotic communities included decreased relative abundance of Acidobacteriota, nitrifying archaea, and methane-oxidizing prokaryotes in the degraded forest sites, while fungal responses included decreased relative abundance of some saprotrophic taxa (e.g. litter saprotrophs). Forest degradation also reduced network connectivity in prokaryotic communities and increased the importance of dispersal limitation in assembling both prokaryotic and fungal communities, suggesting recolonization dynamics drive microbial composition following disturbance. Further, changes in microbial functional groups reflected changes in soil chemical properties—reductions in nitrifying microorganisms corresponded with reduced NO3-N pools in the degraded soils. Overall, our results show that soil microbiota are highly responsive to forest degradation in eucalypt forests and demonstrate that microbial responses to degradation will drive changes in key forest ecosystem functions.
No related grants have been discovered for Kawinwit Kittipalawattanapol.