Smart self-propelled nanoreactors for catalytic environmental remediation. This project aims to develop nanomaterial design and technology to enable the applications of nanotechnology for environmental remediation. Various nanomotors with different asymmetric structures will be fabricated and tested for catalytic and photocatalytic degradation of aqueous pollutants. The physicochemical properties, motion behaviour and catalytic performance will be comprehensively investigated. The outcomes of th ....Smart self-propelled nanoreactors for catalytic environmental remediation. This project aims to develop nanomaterial design and technology to enable the applications of nanotechnology for environmental remediation. Various nanomotors with different asymmetric structures will be fabricated and tested for catalytic and photocatalytic degradation of aqueous pollutants. The physicochemical properties, motion behaviour and catalytic performance will be comprehensively investigated. The outcomes of the project will underpin the development of green technologies for sustainable energy conversion and water treatment. This will provide significant benefits, putting Australia in a leading position in the sustainable development of nanotechnology for sustainable energy supply and transformation as well as environmental and biomedical applications.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100205
Funder
Australian Research Council
Funding Amount
$150,000.00
Summary
A novel high-pressure system for multiple gas adsorption. This facility will equip researchers with analytical capabilities for research in the field of multi-gas adsorption. The facility will be of great significance to clean energy research, such as greenhouse gas emission control and hydrogen production and storage.
Oxide-based high temperature proton exchange membrane fuel cells. Proton exchange membrane fuel cells (PEMFCs) are one of the most efficient energy conversion technologies for producing electricity from fuels such as hydrogen and methanol. Current PEMFCs use precious metal catalysts, and the performance of liquid methanol fuel is disappointingly low due to the inability of polymer or hybrid membranes to operate at temperatures above 160-180 degrees centigrade. This work aims to develop an all ox ....Oxide-based high temperature proton exchange membrane fuel cells. Proton exchange membrane fuel cells (PEMFCs) are one of the most efficient energy conversion technologies for producing electricity from fuels such as hydrogen and methanol. Current PEMFCs use precious metal catalysts, and the performance of liquid methanol fuel is disappointingly low due to the inability of polymer or hybrid membranes to operate at temperatures above 160-180 degrees centigrade. This work aims to develop an all oxide-based PEMFC technology using a recently developed sintered and heteropolyacid functionalised mesoporous silica membrane. The utilisation of all-oxide-PEMFCs using non-precious metal catalysts is expected to significantly enhance the power density, reduce costs, and enhance the commercial viability of PEMFC technologies.Read moreRead less
New mesoporous materials for use in high temperature proton exchange fuel cell membranes. A novel high temperature proton exchange membrane based on heteropolyacid (HPA) functionalised mesoporous silica will be developed. This research into the fundamental materials science of novel proton exchange membranes is expected to impact significantly on the advancement and commercialisation of portable fuel cell devices.
Industry Laureate Fellowships - Grant ID: IL230100039
Funder
Australian Research Council
Funding Amount
$3,516,522.00
Summary
Aqueous sodium batteries for household and smart-grid electricity storage. This project aims to design and commercialise safe, cost-effective, long-lasting, fast-charging, high energy density aqueous sodium-based batteries to store renewable energy for use in households and smart grids. With a focus on developing and scaling technology and in collaboration with industry partners, the project’s expected outcomes include an enhanced ability to store excess energy and modulate its release into a sm ....Aqueous sodium batteries for household and smart-grid electricity storage. This project aims to design and commercialise safe, cost-effective, long-lasting, fast-charging, high energy density aqueous sodium-based batteries to store renewable energy for use in households and smart grids. With a focus on developing and scaling technology and in collaboration with industry partners, the project’s expected outcomes include an enhanced ability to store excess energy and modulate its release into a smart grid during peak demand. Of benefits to Australia, this project will deliver access to reliable, safe and cheap batteries for smart-grid electricity storage in households and a competitive industry manufacturing capability. The downstream benefit is a reduction in energy costs and a contribution to net-zero emissions.
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Establishing nanoscale design principles for non-viral genome engineering. This project aims to develop a bio-nanotechnology platform for non-viral genome engineering using dendronised polymers. The project will advance both fundamental and practical knowledge at the forefront of nanotechnology and cell biology, whilst providing training to the research community. Outcomes from the project will also provide significant benefits, such as positioning Australia at the forefront of genome engineerin ....Establishing nanoscale design principles for non-viral genome engineering. This project aims to develop a bio-nanotechnology platform for non-viral genome engineering using dendronised polymers. The project will advance both fundamental and practical knowledge at the forefront of nanotechnology and cell biology, whilst providing training to the research community. Outcomes from the project will also provide significant benefits, such as positioning Australia at the forefront of genome engineering.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE140100051
Funder
Australian Research Council
Funding Amount
$320,000.00
Summary
An advanced X-ray facility for surface and in-situ materials characterization. An advanced X-ray facility for surface and in-situ materials characterisation: Materials properties are crucial to the performance of devices and structures, and detailed characterisation at a molecular level is important for optimizing new materials. X-rays are a powerful means of achieving the required level of detail in structural characterisation. The aim of this project is to make available an extremely bright X- ....An advanced X-ray facility for surface and in-situ materials characterization. An advanced X-ray facility for surface and in-situ materials characterisation: Materials properties are crucial to the performance of devices and structures, and detailed characterisation at a molecular level is important for optimizing new materials. X-rays are a powerful means of achieving the required level of detail in structural characterisation. The aim of this project is to make available an extremely bright X-ray source with a suite of advanced analytical tools, including surface structural analysis by reflectometry and grazing incidence diffraction and materials structure determination using powder diffraction and microdiffraction at high and low temperatures. The functions of this facility are broad and its applications include materials science, organic electronics, biomaterials and engineering.Read moreRead less
Highly ordered and tuneable mesostructured perfluorosulfonic acid polymers as novel proton exchange membranes for fuel cells. The purpose of the project is to develop an innovative perfluorofonic acid based proton exchange membranes (PEM) with ordered and tuneable mesopores and it is expected that PEM fuel cell power systems based on such new PEMs will have significant impact on the advancement of fuel cell technologies and the reduction in greenhouse gas emission.
Application of microfluidics in engineering functional noble metal nano-materials. High value added nano-materials based on precious metals from gold refining will be developed using continuous flow microfluidic platforms in parallel, in partnership with the Perth Mint (WA Mint). The scalable products will be assessed for application in devices and sensor technology, and as a catalysis for the fine chemical industry.
Understanding graphitization: developing a model for activated carbons. For over 60 years it has remained a puzzle why some carbons graphitise under heating while others do not. The question is of practical importance as oxidation of non-graphitising carbons produces activated carbon, a product of high value with industrial, medical and environmental applications. Using computational and experimental techniques the project will study the graphitisation process and pinpoint the structural element ....Understanding graphitization: developing a model for activated carbons. For over 60 years it has remained a puzzle why some carbons graphitise under heating while others do not. The question is of practical importance as oxidation of non-graphitising carbons produces activated carbon, a product of high value with industrial, medical and environmental applications. Using computational and experimental techniques the project will study the graphitisation process and pinpoint the structural elements which inhibit it. Based on these findings the project aims to develop a nanoscale atomistic model for activated carbons. This is expected to be an important contribution to the field of chemical engineering in which current models of activated carbon neglect either curvature in the network or the presence of oxygen.Read moreRead less