Understanding how bacteria form multicellular biofilm communities on surfaces: the role of cyclic diguanylate as a potent biofilm activator. Bacteria usually exist as multicellular communities called biofilms when attached to surfaces, frequently to the detriment of the environment, industry and health. This project will explore the strategies bacteria use to switch from living as free-floating, individual cells to forming biofilms by studying how bacteria 'switch on' their biofilm genes.
Achieving biodiversity conservation and ecosystem service delivery: the role of landscape structure. Achieving gains for human well-being and, at the same time, conserving biodiversity is the ultimate challenge for conservation policy. This project will develop new understandings and new methods to address this issue, with important impacts on the effectiveness of strategies to conserve biodiversity.
Optimised field delineation of contaminated soils. This project seeks to cost-efficiently identify the contaminated areas of a soil site which will require remediation. There are many thousands of sites contaminated with metals and/or organics across urban and rural Australia and some tens of millions across the world. These sites pose a serious potential threat to human health. Detection (and remediation) of such sites is expensive. The project aims to deliver a cheaper method of detection thro ....Optimised field delineation of contaminated soils. This project seeks to cost-efficiently identify the contaminated areas of a soil site which will require remediation. There are many thousands of sites contaminated with metals and/or organics across urban and rural Australia and some tens of millions across the world. These sites pose a serious potential threat to human health. Detection (and remediation) of such sites is expensive. The project aims to deliver a cheaper method of detection through a novel combination of infra-red and X-ray spectroscopies combined with data-fused soil inference and optimised directed sampling and mapping. This is intended to reduce the economic barrier to detection and remediation, considerably hastening the removal of this health risk. Resulting novel technology could be transferred and commercialised internationally.Read moreRead less
Optimising fire management for a resilient future. Optimising fire management for a resilient future. This project aims to quantify how changes in fire frequency, fire season, invasive weeds and climate interact to affect native species’ persistence. Fire risk management is a conundrum for agencies responsible both for protection of life and property and biodiversity conservation. Global change factors (rainfall decline, warming, invasive species, ecosystem fragmentation) interact with changes i ....Optimising fire management for a resilient future. Optimising fire management for a resilient future. This project aims to quantify how changes in fire frequency, fire season, invasive weeds and climate interact to affect native species’ persistence. Fire risk management is a conundrum for agencies responsible both for protection of life and property and biodiversity conservation. Global change factors (rainfall decline, warming, invasive species, ecosystem fragmentation) interact with changes in fire regime (interval and season) associated with prescribed burning to affect native species’ regeneration capacity. Anticipated outcomes are fuel reduction burning policy and management changes that balance and minimise risk of fire to economy, society and biodiversity.Read moreRead less
Species traits, substrates and stormwater grates: improving the health of urban trees by using polluted stormwater as a resource. This project uses plant traits to select existing and novel tree species for glasshouse studies to quantify the uptake of stormwater and polluting nutrients as well as drought tolerance in stormwater street tree systems. In collaboration with water industry and tree nursery industry partners and a syndicate of local councils, the project aims to install passive stormw ....Species traits, substrates and stormwater grates: improving the health of urban trees by using polluted stormwater as a resource. This project uses plant traits to select existing and novel tree species for glasshouse studies to quantify the uptake of stormwater and polluting nutrients as well as drought tolerance in stormwater street tree systems. In collaboration with water industry and tree nursery industry partners and a syndicate of local councils, the project aims to install passive stormwater street tree systems into existing suburbs and new greenfield developments in Melbourne. Models will be used to design and predict the performance of these stormwater street tree systems, and the glasshouse/field research outputs are expected to refine the leading industry and government relevant urban catchment model.Read moreRead less
Stabilisation of algal biomass harvested from coal seam gas associated water to generate a renewable, high nutrient resource. This project will develop composting technology to stabilise the biomass harvested from coal seam gas ponds. A feature of the project is consideration of toxic algal metabolites, and the potential for the release and degradation of these compounds during stabilisation.
Discovery Early Career Researcher Award - Grant ID: DE200101226
Funder
Australian Research Council
Funding Amount
$426,071.00
Summary
Success and the city: biodiversity responses in urban environments. This project aims to quantify the species traits and environmental conditions that enable wildlife to persist in an increasingly urbanised world. Through developing and testing a framework linking unprecedented urban expansion and biodiversity change, this project will identify favourable conditions that support biodiversity in the face of global urbanisation. Project outcomes will inform appropriate real-world management action ....Success and the city: biodiversity responses in urban environments. This project aims to quantify the species traits and environmental conditions that enable wildlife to persist in an increasingly urbanised world. Through developing and testing a framework linking unprecedented urban expansion and biodiversity change, this project will identify favourable conditions that support biodiversity in the face of global urbanisation. Project outcomes will inform appropriate real-world management actions and equip scientists, policy-makers and planners with tools to forecast the persistence of biodiversity in Australian cities. By discovering the attributes species need to survive city life this project will help prevent future catastrophic declines of global biodiversity in our increasingly urbanised world.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.
Multi-scale recognition: generating meaning from multi-resolution data. The next generation of robots will be able to precisely recognise objects to reason about the world. This project will develop robust recognition systems that will aid robots in providing assistance in populated urban areas as well as in monitoring underwater environments for marine biodiversity preservation.
Interactions between nanoparticles and bacteria. This project aims to understand how nanoparticles interfere with bacterial metabolism, and how these interactions lead to cell death, lysis and dispersal from biofilms. Intensive use of nanomaterials results in their continuously releases into the environment. While various nanoparticles have inhibitory and even toxic effects on microorganisms in ecosystems, the underlying mechanisms are not understood. This project will investigate model organism ....Interactions between nanoparticles and bacteria. This project aims to understand how nanoparticles interfere with bacterial metabolism, and how these interactions lead to cell death, lysis and dispersal from biofilms. Intensive use of nanomaterials results in their continuously releases into the environment. While various nanoparticles have inhibitory and even toxic effects on microorganisms in ecosystems, the underlying mechanisms are not understood. This project will investigate model organisms’ responses to nanoparticles at the cellular, enzymatic and gene expression levels. The findings are expected to help assess the immediate and long-term effect of nanoparticles on ecosystem health, for improved environmental management.Read moreRead less