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Environmental fingerprints of biogeochemical cycles embedded in tree rings: Linking global climate change to local long-term forest productivity. Forests cover one-third of the Earth's land surface and account for 80-90% of plant carbon and 30-40% of soil carbon. Forest carbon stocks and dynamics respond to and interact with global climate change (GCC). Recent tree ring research highlights the worsening impact of GCC and acid deposition on long-term forest productivity in central Europe. This pr ....Environmental fingerprints of biogeochemical cycles embedded in tree rings: Linking global climate change to local long-term forest productivity. Forests cover one-third of the Earth's land surface and account for 80-90% of plant carbon and 30-40% of soil carbon. Forest carbon stocks and dynamics respond to and interact with global climate change (GCC). Recent tree ring research highlights the worsening impact of GCC and acid deposition on long-term forest productivity in central Europe. This project seeks to develop and apply novel tree ring technologies for linking biogeochemical cycles of carbon and nutrients to long-term forest productivity in different regions, and to provide a scientific basis for accounting for long-term forest productivity and carbon stocks in response to future GCC.Read moreRead less
Fingerprints of global climate change and forest management on rhizosphere carbon and nutrient cycling. Using a series of innovative techniques, this project seeks to capture the excellent, exciting opportunities for studying impacts of global climate change (GCC) and forest management on plant-soil-microbe interactions in rhizosphere carbon and nutrient cycling, with two of the world's best GCC forest experiments in Sweden and USA and three long-term forest management experiments in Australia. ....Fingerprints of global climate change and forest management on rhizosphere carbon and nutrient cycling. Using a series of innovative techniques, this project seeks to capture the excellent, exciting opportunities for studying impacts of global climate change (GCC) and forest management on plant-soil-microbe interactions in rhizosphere carbon and nutrient cycling, with two of the world's best GCC forest experiments in Sweden and USA and three long-term forest management experiments in Australia. The successful conduct of this multidisciplinary collaborative research will result in: improved understanding and management of forest ecosystems in response to GCC and effective biodiversity conservation in managed forests; and enhanced international reputation and expertise of the Australian scientists in the relevant research fields.Read moreRead less
How do characteristics of seeds and landscape heterogeneity determine plant spread in new environments? Climate change and exotic invasions are among the greatest threats to Australia's, and the world's, biodiversity. Under a rapidly changing climate many Australian plant species will have to spread across a fragmented landscape to persist. In order to contain or eradicate invasive plant species we need to know how they will spread in novel landscapes. We will develop models which will be used f ....How do characteristics of seeds and landscape heterogeneity determine plant spread in new environments? Climate change and exotic invasions are among the greatest threats to Australia's, and the world's, biodiversity. Under a rapidly changing climate many Australian plant species will have to spread across a fragmented landscape to persist. In order to contain or eradicate invasive plant species we need to know how they will spread in novel landscapes. We will develop models which will be used for invasive plants to predict ecological and evolutionary responses to novel landscapes and novel dispersers and for native plants to predict their spread in to fragmented landscapes. These models can be used to prioritise management actions for species of most conservation concern, and predict how far and fast invasive species will spread.Read moreRead less
Genetic variation of the vulnerable Eucalyptus argophloia, and its development for sustainable hardwood forestry in low rainfall areas. We will examine the biodiversity in a vulnerable species of eucalypt, Eucalyptus argophloia. This species is under threat due to land clearing, and only 1000 trees remain in the wild. E. argophloia has great promise for plantation timber in low rainfall areas of Northern Australia. We will breed superior varieties for plantation forestry designed to cope with cl ....Genetic variation of the vulnerable Eucalyptus argophloia, and its development for sustainable hardwood forestry in low rainfall areas. We will examine the biodiversity in a vulnerable species of eucalypt, Eucalyptus argophloia. This species is under threat due to land clearing, and only 1000 trees remain in the wild. E. argophloia has great promise for plantation timber in low rainfall areas of Northern Australia. We will breed superior varieties for plantation forestry designed to cope with climate change, low rainfall and salinity. This project will help to manage and preserve the species in the wild and create profitable and sustainable timber plantations on marginal lands.Read moreRead less
Impacts of deforestation and afforestation on greenhouse gas emissions, and carbon and water resources in the Daly River catchment, north Australia. Over the last decade, north Australia have been viewed as a potentially exploitable resource, given issues of salinisation, soil acidification, over-allocation of water resources and rainfall declines in south Australian agricultural regions. Improved pastures and plantation forestry are two land uses that may expand in the NT. Clearing of savanna v ....Impacts of deforestation and afforestation on greenhouse gas emissions, and carbon and water resources in the Daly River catchment, north Australia. Over the last decade, north Australia have been viewed as a potentially exploitable resource, given issues of salinisation, soil acidification, over-allocation of water resources and rainfall declines in south Australian agricultural regions. Improved pastures and plantation forestry are two land uses that may expand in the NT. Clearing of savanna vegetation would be required, with implications for greenhouse gas emissions, soil health, water resources and dry season environmental flows. This project will track greenhouse emissions and water use from uncleared and cleared savanna that has been converted to pasture and timber plantations, providing critical understanding of the environmental implication of such land use change in savanna.Read moreRead less