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Forest ecosystem diversity, function and service in response to perturbations: the key regulatory role of biogeochemical cycling. The natural and anthropogenic perturbations such as elevated atmospheric carbon dioxide (CO2), nitrogen(N) deposition, fires and land contamination have transformed much of the land surface on the earth and significantly modified terrestrial biogeochemical cycles in the past century. This project seeks to develop and apply novel nuclear magnetic resonance spectroscopy ....Forest ecosystem diversity, function and service in response to perturbations: the key regulatory role of biogeochemical cycling. The natural and anthropogenic perturbations such as elevated atmospheric carbon dioxide (CO2), nitrogen(N) deposition, fires and land contamination have transformed much of the land surface on the earth and significantly modified terrestrial biogeochemical cycles in the past century. This project seeks to develop and apply novel nuclear magnetic resonance spectroscopy, isotopic and bio-molecular techniques to examine the key role of interactive biogeochemical cycles of carbon and major elements (N, Phosphorous) in regulating forest ecosystem responses to these perturbations. This project will result in improved mitigation and adaptation strategies for such perturbations, thereby restoring and sustaining forest ecosystems and conserving biodiversity in natural ecosystems.Read moreRead less
In vitro propagation (through somatic embryogenesis) of rush and sedge species important for land rehabilitation. This project aims to transform existing propagation methods for rushes and sedges (recalcitrant, but key colonizer species) for restoring critical biodiversity in Australian mine-site restoration. This will be achieved through the process of somatic embryogenesis and will result in cost effective and efficient mass propagation. Significantly, this somatic embryogenesis research will ....In vitro propagation (through somatic embryogenesis) of rush and sedge species important for land rehabilitation. This project aims to transform existing propagation methods for rushes and sedges (recalcitrant, but key colonizer species) for restoring critical biodiversity in Australian mine-site restoration. This will be achieved through the process of somatic embryogenesis and will result in cost effective and efficient mass propagation. Significantly, this somatic embryogenesis research will provide the springboard for development of seed analogues (coated, desiccated somatic embryos) with subsequent economies from bypassing more costly nursery production of whole plants, utilizing existing infrastructure for direct seeding of restoration sites, and reducing dependence on dwindling reserves of wild-harvested seed.Read moreRead less
The physiological ecology of forest succession: explaining shade tolerance variation in evergreen and deciduous trees. This work will strengthen both the theoretical framework and the local knowledge base for sustainable timber production from natural forests, and for habitat restoration programs (National Research Priority 1.5: Sustainable Use of Australia's Biodiversity). These same advances of global and local relevance will also enable better quality input into models predicting vegetation d ....The physiological ecology of forest succession: explaining shade tolerance variation in evergreen and deciduous trees. This work will strengthen both the theoretical framework and the local knowledge base for sustainable timber production from natural forests, and for habitat restoration programs (National Research Priority 1.5: Sustainable Use of Australia's Biodiversity). These same advances of global and local relevance will also enable better quality input into models predicting vegetation dynamics under climate change scenarios (Research Priority 1.7: Responding to climate change & variability). Furthermore, by clarifying relationships of shade tolerance with other stress-tolerance strategies, this work will help us understand the evolutionary potential of local floras to respond to global change.Read moreRead less
Hybridisation and gene flow in Eucalyptus. We propose to use a molecular approach to study hybridisation in eucalypts. We will study the genetic barriers to gene flow and provide base-line data to assess the potential threat of genetic pollution from exotic plantations to our native forest gene pools. We will concentrate our studies on species of subgenus Symphyomyrtus which includes all the major plantation species. This will allow us to extend our long-running studies of hybridisation towar ....Hybridisation and gene flow in Eucalyptus. We propose to use a molecular approach to study hybridisation in eucalypts. We will study the genetic barriers to gene flow and provide base-line data to assess the potential threat of genetic pollution from exotic plantations to our native forest gene pools. We will concentrate our studies on species of subgenus Symphyomyrtus which includes all the major plantation species. This will allow us to extend our long-running studies of hybridisation towards understanding the dynamics and consequences of genetic invasion and help develop guidelines to minimise the risk of genetic pollution.Read moreRead less