Impacts of climate change on coastal floodplain wetland biogeochemistry and surface water quality. The most vulnerable Australian landscapes to global warming driven sea-level rise are our low-lying coastal floodplains. Seawater inundation dramatically affects soil chemistry and water quality. Over 74,000 km2 of the low-lying coastal floodplains of Australia contain acid sulfate soils. For these soils, seawater inundation has the potential to greatly enhance the release of acidity, with a high c ....Impacts of climate change on coastal floodplain wetland biogeochemistry and surface water quality. The most vulnerable Australian landscapes to global warming driven sea-level rise are our low-lying coastal floodplains. Seawater inundation dramatically affects soil chemistry and water quality. Over 74,000 km2 of the low-lying coastal floodplains of Australia contain acid sulfate soils. For these soils, seawater inundation has the potential to greatly enhance the release of acidity, with a high capacity to severely degrade wetlands, estuaries and farmland. This project will directly contribute to our national capacity to assess and manage impacts from climate change, providing greater protection of our coastal floodplains resources.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0226357
Funder
Australian Research Council
Funding Amount
$100,000.00
Summary
Enhancement of VIEPS Stable Isotope Facilities: Environmental and Geological Research. This proposal will enhance the Monash/VIEPS stable isotope facility by automating a variety of analytical procedures. This will increase our throughput of samples, enable a broader range of analyses to be undertaken, and improve accuracy and precision. The enhanced facility will be state-of -the-art and used to support research in a broad range of fields, including: Hydrogeology (groundwater resources, salinit ....Enhancement of VIEPS Stable Isotope Facilities: Environmental and Geological Research. This proposal will enhance the Monash/VIEPS stable isotope facility by automating a variety of analytical procedures. This will increase our throughput of samples, enable a broader range of analyses to be undertaken, and improve accuracy and precision. The enhanced facility will be state-of -the-art and used to support research in a broad range of fields, including: Hydrogeology (groundwater resources, salinity, contaminant studies); Interaction of organic matter with groundwater systems; Cementation and diagenesis in sedimentary basins; Palaeoclimatology; Global carbon cycles; Crustal fluid flow; and Economic geology.Read moreRead less