Special Research Initiatives - Grant ID: SR180100030
Funder
Australian Research Council
Funding Amount
$1,103,883.00
Summary
Development of electrochemically activated sorbents for PFAS defluorination. This project aims to develop a new treatment technology to completely defluorinate per- and poly-fluroalkyl substances (PFAS) and to treat significant water quantities. The majority of existing water treatment technologies are unable to remove PFAS to the desired extent, are prohibitively expensive or are only useful for a very limited lifespan. This project is expected to develop a new treatment technology with the abi ....Development of electrochemically activated sorbents for PFAS defluorination. This project aims to develop a new treatment technology to completely defluorinate per- and poly-fluroalkyl substances (PFAS) and to treat significant water quantities. The majority of existing water treatment technologies are unable to remove PFAS to the desired extent, are prohibitively expensive or are only useful for a very limited lifespan. This project is expected to develop a new treatment technology with the ability to completely defluorinate PFAS, treat significant water quantities and help address many of the pressing concerns facing water treatment operators. This technology is also scalable, and can potentially be used to treat significant quantities of contaminated water.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE180100550
Funder
Australian Research Council
Funding Amount
$356,446.00
Summary
Preserving our rivers: environmental water use in a changing climate. This project aims to develop an 'active management' tool to improve the robustness and transparency of environmental water management. Managing Government investment on environmental water requires decisions on when and where to use water, involving complex trade-offs between competing benefits. This project will develop a tool to address shortcomings in currently available approaches based on the assumption of stationary clim ....Preserving our rivers: environmental water use in a changing climate. This project aims to develop an 'active management' tool to improve the robustness and transparency of environmental water management. Managing Government investment on environmental water requires decisions on when and where to use water, involving complex trade-offs between competing benefits. This project will develop a tool to address shortcomings in currently available approaches based on the assumption of stationary climate, leading to more environmental benefit for less water, and greater resilience in the face of a changing climate.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE210100117
Funder
Australian Research Council
Funding Amount
$427,612.00
Summary
Multiobjective optimisation of reservoir operations under uncertainty. This project aims to address a crucial water resources management problem: how to manage reservoirs under uncertainty. This project expects to develop an optimisation-based framework to improve the delivery of water resources from optimised reservoir operational strategies. Expected outcomes include an innovative tool for multiobjective decision-making under uncertainty, and robust operational strategies catering for real-wor ....Multiobjective optimisation of reservoir operations under uncertainty. This project aims to address a crucial water resources management problem: how to manage reservoirs under uncertainty. This project expects to develop an optimisation-based framework to improve the delivery of water resources from optimised reservoir operational strategies. Expected outcomes include an innovative tool for multiobjective decision-making under uncertainty, and robust operational strategies catering for real-world operational situations, including conflicting objectives, natural variability in system inputs, and future uncertainty due to climate change and population growth. The improved decisions will protect lives and assets, and postpone expensive infrastructure upgrades by maximising benefits from current systems.Read moreRead less
Reducing flood loss - A data-assimilation framework for improving forecasting capability in sparsely gauged regions. Floods are the biggest and severest natural disaster we face year after year. Furthermore, there has been little improvement in our capability to prevent flood damage over past decades. This research proposes a paradigm shift in the way flood forecasting, warning and evacuation proceeds, using 21st century technologies for collecting and incorporating flood related data into exist ....Reducing flood loss - A data-assimilation framework for improving forecasting capability in sparsely gauged regions. Floods are the biggest and severest natural disaster we face year after year. Furthermore, there has been little improvement in our capability to prevent flood damage over past decades. This research proposes a paradigm shift in the way flood forecasting, warning and evacuation proceeds, using 21st century technologies for collecting and incorporating flood related data into existing modelling platforms. It is argued that assimilating real-time satellite soil moisture data into flood models can increase accuracy manifold, even if the images are uncertain. The understanding gained in course of the proposed project has the potential to significantly reduce the damage caused year after year, especially in the data poor regions of the world.Read moreRead less
A unified approach for estimating coastal flood risk. The project aims to develop a unified approach to quantifying flood risk. Because flooding is caused by multiple mechanisms such as extreme rainfall, storm surge and astronomical tide, accurately estimating flood levels in the Australian coastal zone is challenging. By quantifying flood risk in terms of these mechanisms, the project is expected to provide reliable flood risk estimates for both historical settings and future climate scenarios. ....A unified approach for estimating coastal flood risk. The project aims to develop a unified approach to quantifying flood risk. Because flooding is caused by multiple mechanisms such as extreme rainfall, storm surge and astronomical tide, accurately estimating flood levels in the Australian coastal zone is challenging. By quantifying flood risk in terms of these mechanisms, the project is expected to provide reliable flood risk estimates for both historical settings and future climate scenarios. The improved estimation should enable Australian water agencies and policy-makers to effectively design defence infrastructure (e.g. drainage systems) and urban planning policies to adapt to future flood risk.Read moreRead less
ARC Centre for Functional Nanomaterials. The Centre will consist of leading researchers from four Australian universities, four CSIRO divisions, and two US research centres. The vision is to position Australia as a world leader in nanomaterials science and technology. The Centre will involve nanoscale science for building functional nanostructures of materials at the molecular level. It aims to develop new methods and techniques for self-assembling and characterizing nanomaterials with tailorabl ....ARC Centre for Functional Nanomaterials. The Centre will consist of leading researchers from four Australian universities, four CSIRO divisions, and two US research centres. The vision is to position Australia as a world leader in nanomaterials science and technology. The Centre will involve nanoscale science for building functional nanostructures of materials at the molecular level. It aims to develop new methods and techniques for self-assembling and characterizing nanomaterials with tailorable properties. The outcomes will include leading-edge science, the development of human capital, and intellectual property in new materials and products for applications in clean energy, environmental, and health care industries.Read moreRead less
From hazard identification to risk management. From hazard identification to risk management. This project aims to explore health risks from water- and sediment-borne bacteria to recreational users of urban rivers, using a suite of novel molecular microbiological and in-vitro assays and microbial risk assessment modelling. This project also aims to develop source tracking methods to mitigate and manage these risks. The number of bacterial-related water-borne outbreaks associated with recreationa ....From hazard identification to risk management. From hazard identification to risk management. This project aims to explore health risks from water- and sediment-borne bacteria to recreational users of urban rivers, using a suite of novel molecular microbiological and in-vitro assays and microbial risk assessment modelling. This project also aims to develop source tracking methods to mitigate and manage these risks. The number of bacterial-related water-borne outbreaks associated with recreational activities is rising, but waterway managers are under pressure to re-open these rivers for recreation. The project is expected to benefit urban communities by ensuring waterway managers make informed decisions about river recreation.Read moreRead less
A spatial extremes framework for predicting subdaily rainfall intensity. Climate change is causing extreme rainfall intensity to increase globally. The greatest increases occur for short-duration storms lasting up to several hours, bringing a heightened risk of flash-floods that are often extremely hazardous due to their rapid onset. The project aims to develop a new spatial extreme value framework to predict extreme rainfall patterns, using insights on future changes to rainfall triggering mech ....A spatial extremes framework for predicting subdaily rainfall intensity. Climate change is causing extreme rainfall intensity to increase globally. The greatest increases occur for short-duration storms lasting up to several hours, bringing a heightened risk of flash-floods that are often extremely hazardous due to their rapid onset. The project aims to develop a new spatial extreme value framework to predict extreme rainfall patterns, using insights on future changes to rainfall triggering mechanisms (e.g. convective, frontal or orographic). The research aims to provide projections in the form of intensity-frequency-duration curves, areal reduction factors and antecedent rainfall depths. Engineers are expected to use this information to design infrastructure and urban planning policies to adapt to future flood risk.Read moreRead less
Remediation of groundwater using permeable reactive barriers. Permeable reactive barriers are passive subsurface installations that remove contamination from groundwater as it flows through a reactive substrate. This project will develop new permeable reactive barriers that will benefit the nation by building skills and knowledge in an area of growth in Australian industry, namely the rehabilitation of industrial lands and the protection and remediation of Australia's critical groundwater source ....Remediation of groundwater using permeable reactive barriers. Permeable reactive barriers are passive subsurface installations that remove contamination from groundwater as it flows through a reactive substrate. This project will develop new permeable reactive barriers that will benefit the nation by building skills and knowledge in an area of growth in Australian industry, namely the rehabilitation of industrial lands and the protection and remediation of Australia's critical groundwater sources. The project is aimed at remediating an industrially contaminated site in the Hunter Valley, New South Wales, thereby contributing to the environmental improvement of that region. The technology developed will have wide application to other sites, both nationally and internationally.Read moreRead less
Untangling the mechanisms of nutrient export from agricultural catchments. This projects aims to better understand the factors controlling nutrient retention and removal within agricultural catchments and how climate and land use change will affect this. This project will combine novel approaches to investigate nutrient sources, removal and bioavailability with geochemical tracers to better understand nutrient flow and removal pathways. This new knowledge will be captured in state of the art m ....Untangling the mechanisms of nutrient export from agricultural catchments. This projects aims to better understand the factors controlling nutrient retention and removal within agricultural catchments and how climate and land use change will affect this. This project will combine novel approaches to investigate nutrient sources, removal and bioavailability with geochemical tracers to better understand nutrient flow and removal pathways. This new knowledge will be captured in state of the art modelling approaches that will help improve land management practices, leading to reduced nutrient loads and improved water quality in receiving waters such as the Gippsland Lakes.Read moreRead less