Linkage Infrastructure, Equipment And Facilities - Grant ID: LE200100083
Funder
Australian Research Council
Funding Amount
$310,000.00
Summary
A 4D habitat-modelling facility to support marine ecological research. The loss and modification of natural habitats is a major threat to biodiversity that requires evidence-based management supported by excellent science. To this end, this project will create a facility for 4D habitat modelling (i.e. assessing changes in 3D habitat structure over time) that will underpin research innovation in marine systems. The new aerial and subtidal image acquisition technology will also be used to accurate ....A 4D habitat-modelling facility to support marine ecological research. The loss and modification of natural habitats is a major threat to biodiversity that requires evidence-based management supported by excellent science. To this end, this project will create a facility for 4D habitat modelling (i.e. assessing changes in 3D habitat structure over time) that will underpin research innovation in marine systems. The new aerial and subtidal image acquisition technology will also be used to accurately measure changes in marine plants and algae over time, improve habitats provided by coastal protection infrastructure and support ecological field research. The new equipment will allow scaling up of field experiments and monitoring to enhance their impact and capacity to support effective management.Read moreRead less
New tools to detect ecological effects of contaminants in estuaries. Identifying risks to estuarine environments from pollutants is difficult for environmental managers, who must choose between laboratory toxicity testing that is precise, but hard to generalise to field situations, and more realistic field-based monitoring, which is expensive, with a high signal to noise ratio. New molecular techniques may provide more options. Metabolomics can provide insights into the health of animals, and ec ....New tools to detect ecological effects of contaminants in estuaries. Identifying risks to estuarine environments from pollutants is difficult for environmental managers, who must choose between laboratory toxicity testing that is precise, but hard to generalise to field situations, and more realistic field-based monitoring, which is expensive, with a high signal to noise ratio. New molecular techniques may provide more options. Metabolomics can provide insights into the health of animals, and ecogenomics offers a way to rapidly assess the composition of an ecological community. These techniques offer great promise, but they must be cross-validated against existing methods to derive the best ’toolbox’. Working with Melbourne Water and CSIRO the investigators aim to do this using demonstration estuaries in Victoria.Read moreRead less
Genetic solution or dilution: can selective breeding future-proof oysters? This project aims to test whether the flow of beneficial genes from farmed oysters into wild oysters can make natural oyster beds and the ecological communities that they support more resilient to environmental change. Wild oysters are critical to the function of coastal ecosystems. However, wild oyster populations are threatened by environmental change in Australia and around the world. Selectively bred oysters bearing s ....Genetic solution or dilution: can selective breeding future-proof oysters? This project aims to test whether the flow of beneficial genes from farmed oysters into wild oysters can make natural oyster beds and the ecological communities that they support more resilient to environmental change. Wild oysters are critical to the function of coastal ecosystems. However, wild oyster populations are threatened by environmental change in Australia and around the world. Selectively bred oysters bearing stress resistance genotypes are now commercially farmed in many estuaries on Australia's east coast and may be used to bolster wild oyster populations. This project endeavours to develop novel genetic strategies to future-proof oysters. Thus, the outcome of this project has potential to benefit entire ecosystems that depend upon oysters.Read moreRead less
Creating coolspots: eco-engineering heat-resistant intertidal communities. This project aims to identify structural characteristics of marine intertidal habitat patches, formed by seaweeds and shellfish, that protect associated species from thermal extremes. This project will generate new knowledge about how thermally sensitive intertidal species can persist in stressful environments. Expected outcomes of this project
include new approaches for building heat-tolerant ecological communities on co ....Creating coolspots: eco-engineering heat-resistant intertidal communities. This project aims to identify structural characteristics of marine intertidal habitat patches, formed by seaweeds and shellfish, that protect associated species from thermal extremes. This project will generate new knowledge about how thermally sensitive intertidal species can persist in stressful environments. Expected outcomes of this project
include new approaches for building heat-tolerant ecological communities on coastal infrastructure, and improved tools for predicting the response of intertidal seaweeds and animals to environmental change. The results of this project will benefit coastal management by identifying conservation and rehabilitation strategies that maximise the
resilience of coastal ecosystems to environmental change.Read moreRead less
Resolving the geochemistry of coastal floodplain blackwaters. Deoxygenated dead zones are a rapidly growing global crisis in coastal areas. A major cause of dead zones in our estuaries is the formation and release of blackwaters from coastal wetlands. This project will provide the knowledge necessary to manage blackwaters in these wetlands and to greatly improve the health and sustainability of our estuaries.
Discovery Early Career Researcher Award - Grant ID: DE150101477
Funder
Australian Research Council
Funding Amount
$360,000.00
Summary
Identifying a new source of natural volatile organohalogens. Natural volatile organohalogens have recently been linked to significant atmospheric ozone depletion. The fundamental reactions controlling their emission and fate are unresolved within the international scientific literature. This project aims to use novel geochemical techniques to determine the role of ultraviolet radiation in organohalogen emissions from degraded saline and acidic landscapes. The expected outcome will shift our unde ....Identifying a new source of natural volatile organohalogens. Natural volatile organohalogens have recently been linked to significant atmospheric ozone depletion. The fundamental reactions controlling their emission and fate are unresolved within the international scientific literature. This project aims to use novel geochemical techniques to determine the role of ultraviolet radiation in organohalogen emissions from degraded saline and acidic landscapes. The expected outcome will shift our understanding of natural volatile organohalogens and predictions of stratospheric ozone recovery. The project also aims to systematically resolve the feedback between elevated ultraviolet radiation and ozone layer depletion, and is therefore highly innovative.Read moreRead less
Testing the waters: impacts of contaminants on ecosystem structure and function in urban waterways. To ensure that people can swim, catch fish and enjoy the beauty of urban waterways we need to be able to predict the effects of more than one stressor at a time. This project will determine how nutrients and metals affect our waterways. Findings will help prioritise management actions that protect biodiversity and human uses of these systems.
Managing the existing and emerging threats from coastal flow slides. This project aims to develop the first management strategies for coastal flow slides. This project expects to generate new knowledge on how flow slides are triggered, propagate inland and undermine structures. Expected outcomes include globally applicable novel models and management approaches developed by an interdisciplinary team of coastal and geotechnical engineers and coastal geomorphologist using innovative data. This is ....Managing the existing and emerging threats from coastal flow slides. This project aims to develop the first management strategies for coastal flow slides. This project expects to generate new knowledge on how flow slides are triggered, propagate inland and undermine structures. Expected outcomes include globally applicable novel models and management approaches developed by an interdisciplinary team of coastal and geotechnical engineers and coastal geomorphologist using innovative data. This is likely to provide significant benefits for planning and managing structures along coasts and bays against destructive flow slides. The project will enable the design and implementation of coastal works to protect existing structures against flow slides risks emerging with rising sea level.Read moreRead less
Unravelling the rhizosphere redox-cycling of iron, sulphur and carbon in re-flooded acidic wetlands. This project will reveal how major re-flooding will influence the cycling of iron, sulphur and carbon in re-flooded acidic, freshwater wetlands. By resolving current biogeochemical uncertainties, this project will generate the necessary knowledge platform to underpin wise long-term management of these sensitive and unique landscapes.
Discovery Early Career Researcher Award - Grant ID: DE150100461
Funder
Australian Research Council
Funding Amount
$360,000.00
Summary
Early Detection of Seagrass Habitat Loss Caused by Eutrophication. Eutrophication (nutrient over-enrichment) caused by a host of anthropogenic activities is recognised as the most widespread cause of seagrass loss. In order to effectively control seagrass loss, there is an urgent need to determine the link between eutrophication and seagrass loss. This project aims to undertake an innovative 'omics approach (transcriptomics and metabolomics) to develop an early-warning system for seagrass loss. ....Early Detection of Seagrass Habitat Loss Caused by Eutrophication. Eutrophication (nutrient over-enrichment) caused by a host of anthropogenic activities is recognised as the most widespread cause of seagrass loss. In order to effectively control seagrass loss, there is an urgent need to determine the link between eutrophication and seagrass loss. This project aims to undertake an innovative 'omics approach (transcriptomics and metabolomics) to develop an early-warning system for seagrass loss. The acclimation and plasticity of seagrass to sub-lethal stress induced by eutrophication will be investigated at the molecular and biochemical levels. This will allow mitigation responses such as altered catchment management processes to prevent damage before meadows are lost.Read moreRead less