Surface ligation of nanomaterials for biomedical applications . The project aims to explore the synergistic effects co-ligands for target recognition and biofouling protection in nanoparticle surface patterns to enable practical atomic scale precision engineering of efficient and biofouling resistant nanosensors. The project will fundamentally characterise interfacial interactions and dynamics of ligated nano-surfaces and biomolecules via advanced computer modelling. Outcomes should include pra ....Surface ligation of nanomaterials for biomedical applications . The project aims to explore the synergistic effects co-ligands for target recognition and biofouling protection in nanoparticle surface patterns to enable practical atomic scale precision engineering of efficient and biofouling resistant nanosensors. The project will fundamentally characterise interfacial interactions and dynamics of ligated nano-surfaces and biomolecules via advanced computer modelling. Outcomes should include practical molecular design guidelines for functional ligands and predicted optimal patterns for combining functional and antifouling ligands on gold nanomaterials for biosensing technologies. The advanced predictive modelling capabilities will facilitate future practical engineering of efficient biomedical devices.Read moreRead less
Safe and efficient biomedical nanomaterials. This project aims to rationally engineer nanomaterials with controlled biological responses. Nanomaterials are becoming widespread in biomedicine and engineering, but are inefficient and unsafe. This project will develop atomic scale models to understand interactions between engineered nanoparticles and the crowded cellular environment. It will design extremely sensitive biosensors and theranostic nanodevices combining medical imaging capacity with pr ....Safe and efficient biomedical nanomaterials. This project aims to rationally engineer nanomaterials with controlled biological responses. Nanomaterials are becoming widespread in biomedicine and engineering, but are inefficient and unsafe. This project will develop atomic scale models to understand interactions between engineered nanoparticles and the crowded cellular environment. It will design extremely sensitive biosensors and theranostic nanodevices combining medical imaging capacity with precision targeted drug delivery to improve efficiency and safety of nanomaterials for biomedical applications in both vitro and in vivo enabling cost effective early diagnostics and more efficient treatments.Read moreRead less
Understanding biomolecular interactions of nanoparticles for engineering efficient biomedical materials and devices. Recent studies suggest that proteins bind differently to nano-patterned materials. This phenomenon holds a great potential for engineering of novel materials and devices for biomedical applications. At the same time, there are increasing concerns due to formation of biomolecular "coronas" of nanoparticles which can change their biological identity. This project will develop knowle ....Understanding biomolecular interactions of nanoparticles for engineering efficient biomedical materials and devices. Recent studies suggest that proteins bind differently to nano-patterned materials. This phenomenon holds a great potential for engineering of novel materials and devices for biomedical applications. At the same time, there are increasing concerns due to formation of biomolecular "coronas" of nanoparticles which can change their biological identity. This project will develop knowledge of the molecular mechanisms of nanomaterials interactions with molecular components of biological environment which will be exploited to improve molecular recognition needed in biosensors and drug delivery applications. The project outcomes will help formulate rational design principles for efficient biomedical materials and nanodevices.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100128
Funder
Australian Research Council
Funding Amount
$300,000.00
Summary
High performance analytical tools to strengthen clean energy research. High performance analytical tools are vital to the success of emerging research fields of national priority. By filling a gap in materials routine characterisation capabilities, the equipment requested will lead to major advances in fundamental and applied research aimed at carbon abatement and clean energy technologies. This includes technologies for clean energy generation by solar means and from decarbonised fossil fuels, ....High performance analytical tools to strengthen clean energy research. High performance analytical tools are vital to the success of emerging research fields of national priority. By filling a gap in materials routine characterisation capabilities, the equipment requested will lead to major advances in fundamental and applied research aimed at carbon abatement and clean energy technologies. This includes technologies for clean energy generation by solar means and from decarbonised fossil fuels, efficient energy storage systems, advanced fuel cells for electricity generation, and hydrogen as the universal energy vector. Advancement of these technologies will bring solutions to the grand challenges facing Australia and in turn benefit industry and society.
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Rechargeable lithium carbon dioxide battery - catalyst design to prototype . This project aims to develop a new concept of rechargeable lithium carbon dioxide batteries and scaled-up prototypes. Such a battery will be first of its kind to show high power comparable to gasoline and superior rechargeability over existing gas-involved batteries, ensuring realistic use for industrial purposes. Expected outcomes include 2-dimensional catalysts made from earth-abundant elements lowering large-scale pr ....Rechargeable lithium carbon dioxide battery - catalyst design to prototype . This project aims to develop a new concept of rechargeable lithium carbon dioxide batteries and scaled-up prototypes. Such a battery will be first of its kind to show high power comparable to gasoline and superior rechargeability over existing gas-involved batteries, ensuring realistic use for industrial purposes. Expected outcomes include 2-dimensional catalysts made from earth-abundant elements lowering large-scale production cost, a novel but reliable working principle based on reversible carbon dioxide/oxalate conversion, and prototypes featuring high specific capacity, large energy density and excellent durability. Via industrial pilot trials, commercial benefits will be fast tracked for energy security and carbon dioxide utilisation.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE230101068
Funder
Australian Research Council
Funding Amount
$454,554.00
Summary
Direct Electrolysis of Amine Captured CO2 for Producing Syngas. This project aims to develop electrolysis of amine captured carbon dioxide (CO2) technology to integrate CO2 capture and syngas production powered by renewable electricity. The aqueous amine captured CO2 will be directly electrolysed without CO2 desorption, compression, and purification, featuring extremely high efficiency and cost-effectiveness. Expected outcomes include the delivery of suitable amines, a family of chemically and s ....Direct Electrolysis of Amine Captured CO2 for Producing Syngas. This project aims to develop electrolysis of amine captured carbon dioxide (CO2) technology to integrate CO2 capture and syngas production powered by renewable electricity. The aqueous amine captured CO2 will be directly electrolysed without CO2 desorption, compression, and purification, featuring extremely high efficiency and cost-effectiveness. Expected outcomes include the delivery of suitable amines, a family of chemically and structurally controlled electrocatalysts, an in-depth understanding of CO2 electrolysis mechanisms, and the demonstration of robust electrolyser prototypes. This project will provide significant benefits to Australia’s energy and environmental security, and boost its clean energy industry and economic growth.Read moreRead less
Engineering two dimensional polymers for membrane-based chemical separation. This project aims to develop novel two-dimensional polymers with precisely controlled pore-sizes for preparing membrane materials which can efficiently separate these gaseous chemicals at ambient temperatures. Key industrial chemical mixtures with similar size and boiling points are difficult to separate by conventional distillation methods. Currently, purification of olefins alone accounts for 0.3% of global energy use ....Engineering two dimensional polymers for membrane-based chemical separation. This project aims to develop novel two-dimensional polymers with precisely controlled pore-sizes for preparing membrane materials which can efficiently separate these gaseous chemicals at ambient temperatures. Key industrial chemical mixtures with similar size and boiling points are difficult to separate by conventional distillation methods. Currently, purification of olefins alone accounts for 0.3% of global energy use. The expected outcomes of the project will have a huge impact on industrial purification processing by providing a disruptive membrane technology, and will significantly reduce energy consumption and open up new routes for resources.Read moreRead less
Perovskite-Based Ferroelectrics for Solar Fuel Production. This project aims to develop perovskite-based ferroelectrics for photocatalytic carbon dioxide reduction to produce solar fuels. It is expected to reveal the relationship of ferroelectric polarisation and photocatalytic behaviour, thereby promoting solar energy utilisation and greenhouse gas reduction. Expected outcomes include delivery of a novel family of chemically and structurally controlled ferroelectrics and catalytic reaction prot ....Perovskite-Based Ferroelectrics for Solar Fuel Production. This project aims to develop perovskite-based ferroelectrics for photocatalytic carbon dioxide reduction to produce solar fuels. It is expected to reveal the relationship of ferroelectric polarisation and photocatalytic behaviour, thereby promoting solar energy utilisation and greenhouse gas reduction. Expected outcomes include delivery of a novel family of chemically and structurally controlled ferroelectrics and catalytic reaction prototypes for efficient carbon dioxide photoreduction, and in-depth understanding of structure-performance correlation to guide future polar catalysts design. This project should provide significant benefits in minimising fossil fuel consumption, increasing energy security, and expanding clean energy industry.Read moreRead less
Monolithic Solar Thermal Photocatalytic Membrane for Hydrogen Production. This ambitious project aims to develop a new concept of monolithic membranes composed of photocatalysts embedded in highly efficient solar thermal graphene. Such a membrane will be first of its kind and is able to utilise full solar spectrum for scalable seawater desalination and direct splitting to produce hydrogen without the need to concentrate sunlight. Expected outcomes include chemically and structurally tailored mem ....Monolithic Solar Thermal Photocatalytic Membrane for Hydrogen Production. This ambitious project aims to develop a new concept of monolithic membranes composed of photocatalysts embedded in highly efficient solar thermal graphene. Such a membrane will be first of its kind and is able to utilise full solar spectrum for scalable seawater desalination and direct splitting to produce hydrogen without the need to concentrate sunlight. Expected outcomes include chemically and structurally tailored membranes and 2D floating prototypes for real life hydrogen production, and in-depth understanding of working mechanism to facilitate up-scaled renewable hydrogen generation. Significant benefits in minimising fossil fuel consumption, increasing energy security, and expanding competitive clean energy industry are promised.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE140100104
Funder
Australian Research Council
Funding Amount
$500,000.00
Summary
Collaborative facility for high resolution fabrication, imaging, and characterisation of nanostructured materials. Collaborative facility for high resolution fabrication, imaging, and characterisation of nanostructured materials: The development of the next generation of electronic, optical, and biomedical devices requires methods that can quickly manipulate and characterise matter at the nanoscale. This project will establish new tools that will allow researchers to build novel device structure ....Collaborative facility for high resolution fabrication, imaging, and characterisation of nanostructured materials. Collaborative facility for high resolution fabrication, imaging, and characterisation of nanostructured materials: The development of the next generation of electronic, optical, and biomedical devices requires methods that can quickly manipulate and characterise matter at the nanoscale. This project will establish new tools that will allow researchers to build novel device structures and analyse them at nanoscale spatial resolutions. The new facilities are required to meet the demands of a growing number of innovative projects being undertaken within a large multidisciplinary consortium of research groups. The facilities will be housed in state-of-the art laboratories and managed as open access resources for researchers which will enable advances in the areas of energy harvesting, environmental monitoring, and electronics.Read moreRead less