Discovery Early Career Researcher Award - Grant ID: DE170100042
Funder
Australian Research Council
Funding Amount
$360,000.00
Summary
Virtual reality for planning of green urban water infrastructure. This project aims to research the planning-technical-social dynamics of Water Sensitive Urban Design (WSUD) infrastructure. WSUD management has become financially and logistically unsustainable due to major urban growth and a rapid uptake in WSUD assets. Solving this problem is, however, complex, as stakeholders have conflicting needs and tacit knowledge that is difficult to quantify. Using emerging virtual reality technology, par ....Virtual reality for planning of green urban water infrastructure. This project aims to research the planning-technical-social dynamics of Water Sensitive Urban Design (WSUD) infrastructure. WSUD management has become financially and logistically unsustainable due to major urban growth and a rapid uptake in WSUD assets. Solving this problem is, however, complex, as stakeholders have conflicting needs and tacit knowledge that is difficult to quantify. Using emerging virtual reality technology, participatory planning and operational models, this project intends to improve WSUD modelling science through integrated modelling. The anticipated outcome is more holistic and economically efficient planning of WSUD layouts in future cities. This is expected to address growing concerns about adequately managing these systems and ensure that they deliver intended environmental protection, liveability and public health benefits.Read moreRead less
Development of the thinnest possible, multifunctional DNA-nanoparticle membranes for ultrafast filtration and smart sensing. Development of ultrathin and multifunctional membranes is currently in urgent need to improve our technologies in energy, environment and healthcare. This project will apply innovative nanobiomaterials to build such membrane systems and establish the design rules and develop key technologies.
Discovery Early Career Researcher Award - Grant ID: DE150101617
Funder
Australian Research Council
Funding Amount
$330,000.00
Summary
Novel Three Dimensional Porous Boron Nitride Foam for Water Cleaning. This project aims to develop new three-dimensional (3D) porous nanomaterials of boron nitride (BN) foam with excellent sorption properties for water purification. New chemical synthesis approaches will be used to produce 3D porous BN foams with high porosity, large surface area and high mechanical stability leading to a high adsorption capacity, easy regeneration and excellent recycle ability for water purification. The expect ....Novel Three Dimensional Porous Boron Nitride Foam for Water Cleaning. This project aims to develop new three-dimensional (3D) porous nanomaterials of boron nitride (BN) foam with excellent sorption properties for water purification. New chemical synthesis approaches will be used to produce 3D porous BN foams with high porosity, large surface area and high mechanical stability leading to a high adsorption capacity, easy regeneration and excellent recycle ability for water purification. The expected outcomes include a new class of light absorbent materials, new production techniques and a high efficiency water cleaning technique.Read moreRead less
Multiscale physics for enhanced oil recovery. The project aims to develop a multiscale mathematical and laboratory modelling methodology for combined enhanced oil recovery (EOR) and CO2 storage, and synthesise the technology for Santos’s Mulberry oilfield as a test case. The multidisciplinary team will develop advanced reservoir- and laboratory-scale mathematical models and novel laboratory methods to enhance the reliability of modern EOR and CO2 storage and increase its uptake by companies in A ....Multiscale physics for enhanced oil recovery. The project aims to develop a multiscale mathematical and laboratory modelling methodology for combined enhanced oil recovery (EOR) and CO2 storage, and synthesise the technology for Santos’s Mulberry oilfield as a test case. The multidisciplinary team will develop advanced reservoir- and laboratory-scale mathematical models and novel laboratory methods to enhance the reliability of modern EOR and CO2 storage and increase its uptake by companies in Australia and globally. The expected outcomes are a pioneering methodology with environmental benefits without additional drilling and reduction of greenhouse effect, and economic benefit to the Australian oil industry through increases in productivity.Read moreRead less
New nanotechnology controlling wettability in unconventional gas reservoirs. This project aims to develop new nanoparticle technologies to change rock wettability and significantly increase gas production from shale and coal seam gas fields. The project plans to use a unique combination of new theoretical models for suspension transport in fractures and innovative mathematical modelling supported by laboratory studies and validated against field results, to test and develop the new strategies fo ....New nanotechnology controlling wettability in unconventional gas reservoirs. This project aims to develop new nanoparticle technologies to change rock wettability and significantly increase gas production from shale and coal seam gas fields. The project plans to use a unique combination of new theoretical models for suspension transport in fractures and innovative mathematical modelling supported by laboratory studies and validated against field results, to test and develop the new strategies for Australian gas fields. The project is expected to improve understanding of complex physical phenomena associated with natural gas production and to deliver economic benefit to the Australian gas industry.Read moreRead less