Linkage Infrastructure, Equipment And Facilities - Grant ID: LE180100053
Funder
Australian Research Council
Funding Amount
$358,031.00
Summary
A national facility for the analysis of pyrogenic carbon. This project aims to develop a national facility for pyrogenic carbon analysis. Pyrogenic carbon is a poorly constrained, slow-cycling terrestrial carbon pool with significant carbon sequestration potential. The project expects to expand the newly developed hydrogen pyrolysis analytical capability to provide high throughput, robust measurement of the abundance and isotope composition of pyrogenic carbon in soils and sediments. This will p ....A national facility for the analysis of pyrogenic carbon. This project aims to develop a national facility for pyrogenic carbon analysis. Pyrogenic carbon is a poorly constrained, slow-cycling terrestrial carbon pool with significant carbon sequestration potential. The project expects to expand the newly developed hydrogen pyrolysis analytical capability to provide high throughput, robust measurement of the abundance and isotope composition of pyrogenic carbon in soils and sediments. This will provide significant benefit, such as the ability to make significant advances in areas as diverse as geochronology, archaeology, palaeoecology, soil science geomorphology and carbon cycle/sequestration science.Read moreRead less
Soil ecology in the 21st century - a crucial role in land management. Recent technological advances have helped us discover the role of soil ecology in achieving sustainability in Australia. This project will develop ways to take this complex knowledge and translate it into forms that can be used by land managers. This work will focus on soil carbon sequestration, but is relevant to many other environmental issues.
Optimal management of coastal ecosystems for blue carbon sequestration. Optimal management of coastal ecosystems for blue carbon sequestration. This project aims to develop decision tools to predict how different management plans could affect the persistence of coastal ecosystems and their capacity to sequester carbon. Coastal ‘blue carbon’ ecosystems (seagrasses, saltmarshes, mangroves) are among Earth’s most efficient carbon sinks, but coastal development and climate change threaten their capa ....Optimal management of coastal ecosystems for blue carbon sequestration. Optimal management of coastal ecosystems for blue carbon sequestration. This project aims to develop decision tools to predict how different management plans could affect the persistence of coastal ecosystems and their capacity to sequester carbon. Coastal ‘blue carbon’ ecosystems (seagrasses, saltmarshes, mangroves) are among Earth’s most efficient carbon sinks, but coastal development and climate change threaten their capacity to sequester carbon. Resource managers urgently need guidance to manage coasts to minimise carbon losses and maximise gains. This project is expected to develop knowledge of how to manage blue carbon ecosystems to achieve maximum carbon sequestration capacity, and to put Australia at the forefront of international efforts to incorporate coastal carbon within carbon dioxide mitigation strategies.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100098
Funder
Australian Research Council
Funding Amount
$600,000.00
Summary
Advanced facility for next generation sustainable energy, biomedical & nano-imaging optical fibre technologies. Remote optical fibre technologies are the way forward for effective and safe monitoring of many industries, and will play a big part in the sustainability of Australia's core oil, gas and alternative energy sectors. They are equally important to health industry applications, particularly in medical and imaging technologies. This facility brings together world-class Australian expertise ....Advanced facility for next generation sustainable energy, biomedical & nano-imaging optical fibre technologies. Remote optical fibre technologies are the way forward for effective and safe monitoring of many industries, and will play a big part in the sustainability of Australia's core oil, gas and alternative energy sectors. They are equally important to health industry applications, particularly in medical and imaging technologies. This facility brings together world-class Australian expertise—from across nine universities—in advanced structured optical fibres, complex fibre diagnostic systems, nanoscale imaging, and environment monitoring, to design and implement the next generation of technologies that will reduce the impact of climate change through reduced energy consumption and vastly improved health diagnostics.Read moreRead less
Urban biochar: towards prescriptive biochar use for maximum economic productivity and sustainability benefits in urban environments. This project will develop a life cycle assessment of waste management options for green waste and biosolids based on a clear understanding of productivity benefits of urban biochar application to high value production systems.
Linking soil acidification with carbon dynamics in Australian agroecosystems. The ability to mitigate climate change by sequestering soil carbon may be limited in acidic soils, which are prevalent in Australia. The project will investigate the link between carbon cycling, soil acidification and liming, and provide important knowledge to identify agricultural practices which have the capacity to build soil carbon.
Fires, black carbon, greenhouse gas emissions and the carbon balance of southern sclerophyll forests. Ecologically sustainable forest management requires an understanding of the role of fire in the carbon balance of native forests, and in Australia's overall carbon balance. Fires are crucial to both this carbon balance and to the ecology of the forests. This project will help forest managers make decisions about using prescribed fire to manage fuels while at the same time managing carbon. An ....Fires, black carbon, greenhouse gas emissions and the carbon balance of southern sclerophyll forests. Ecologically sustainable forest management requires an understanding of the role of fire in the carbon balance of native forests, and in Australia's overall carbon balance. Fires are crucial to both this carbon balance and to the ecology of the forests. This project will help forest managers make decisions about using prescribed fire to manage fuels while at the same time managing carbon. An aim of management is to identify fire regimes that will optimise the carbon outcome as well as provide protection to life and property. This project will help managers meet that aim by developing a quantitative understanding of how much stable, black carbon (charcoal) is produced and how it affects other soil processes.Read moreRead less
Ecosystem services from large urban green spaces - the biodiversity and carbon benefit of urban golf courses. Golf courses in our cities provide localised cooling, Carbon sequestration and biodiversity habitat benefits. To safeguard these urban green spaces from development these ecosystem services need to be quantified. This project will quantify the Carbon and biodiversity benefit of urban golf courses so that they can be better valued and managed for the future.
Methane uptake of forest soils. This project will provide a detailed understanding of capacity of soils in Australia to sequester the greenhouse gas methane. It will identify the main factors and processes controlling methane uptake in soils and improve predictive models will allow us to predict methane uptake in the future.
Maximising carbon sequestration in freshwater wetlands. Maximising carbon sequestration in freshwater wetlands. This project aims to determine how manipulation of wetland hydrology can alter sulphur and iron cycling to inhibit methane emission and improve wetland net-carbon sequestration. Wetlands are among earth's most efficient ecosystems for carbon sequestration, but methane emission can offset this capacity. Redox cycling of sulphur and iron in wetlands can inhibit methane emission, but the ....Maximising carbon sequestration in freshwater wetlands. Maximising carbon sequestration in freshwater wetlands. This project aims to determine how manipulation of wetland hydrology can alter sulphur and iron cycling to inhibit methane emission and improve wetland net-carbon sequestration. Wetlands are among earth's most efficient ecosystems for carbon sequestration, but methane emission can offset this capacity. Redox cycling of sulphur and iron in wetlands can inhibit methane emission, but the precise biogeochemical processes and their efficiency are very poorly constrained due to a lack of studies—especially in Australian freshwater wetlands. This project is expected to inhibit methane emission in freshwater wetlands and maximise their net carbon sequestration efficiency.Read moreRead less