The Impact of Trawling on Nitrogen Removal through Sediment Denitrification in Western Moreton Bay. Nutrient enrichment of coastal waters is a national problem requiring urgent action. Sediment denitrification is one of the few natural processes capable of counteracting the process of eutrophication. Although trawling is undertaken in coastal water bodies around Australia the impact on sediment denitrification and the nitrogen budgets of coastal systems has never been considered. Many hundred's ....The Impact of Trawling on Nitrogen Removal through Sediment Denitrification in Western Moreton Bay. Nutrient enrichment of coastal waters is a national problem requiring urgent action. Sediment denitrification is one of the few natural processes capable of counteracting the process of eutrophication. Although trawling is undertaken in coastal water bodies around Australia the impact on sediment denitrification and the nitrogen budgets of coastal systems has never been considered. Many hundred's of millions of dollars are likely to be spent over the next ten years on the management of nitrogen enrichment of Australia's coastal waters. This study will quantify the impact of trawling on sediment denitrification; information which is critical for the efficient allocation of management resources.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0668226
Funder
Australian Research Council
Funding Amount
$186,000.00
Summary
A new X-ray spectrometer facility for VIEPS: major and trace element characterisation of geological materials. Australia has a well-earned reputation as a leading innovator in analytical geochemistry and the acquisition of this instrumentation will reinforce that standing. The equipment will support a broad range of research activities and enhance our capability for research training at Honours and post-graduate student level. In addition this project addresses directly our current National Rese ....A new X-ray spectrometer facility for VIEPS: major and trace element characterisation of geological materials. Australia has a well-earned reputation as a leading innovator in analytical geochemistry and the acquisition of this instrumentation will reinforce that standing. The equipment will support a broad range of research activities and enhance our capability for research training at Honours and post-graduate student level. In addition this project addresses directly our current National Research Priority 'an environmentally sustainable Australia', and priority goals 'Developing deep earth resources' and 'Responding to climate change and variability'Read moreRead less
The Role of Water in Precambrian Ultramafic Magmatism: Insights from an In-Situ Microbeam and Nanobeam Assessment of Hydromagmatic Amphibole. Hydromagmatic amphibole in some Precambrian (>600 million years old) komatiites and other ultramafic rocks in Australia, Canada and Russia indicates >3% water in the parental magmas. This magmatic water could be crustal or mantle in origin. Constraints on the water source would profoundly impact concepts of Precambrian crustal evolution and water recycling ....The Role of Water in Precambrian Ultramafic Magmatism: Insights from an In-Situ Microbeam and Nanobeam Assessment of Hydromagmatic Amphibole. Hydromagmatic amphibole in some Precambrian (>600 million years old) komatiites and other ultramafic rocks in Australia, Canada and Russia indicates >3% water in the parental magmas. This magmatic water could be crustal or mantle in origin. Constraints on the water source would profoundly impact concepts of Precambrian crustal evolution and water recycling. The ultimate goal of this project is to provide constraints on the role of water in early Earth magmatism, through in situ microbeam and nanobeam analysis of the amphibole to produce an integrated trace element and isotopic dataset for geologically and chemically diverse types of Precambrian ultramafic rocks.Read moreRead less