Combating Antimicrobial Resistance with Bismuth, Gallium and Indium. This research project focuses on the design, development, and application of new bismuth, gallium and indium compounds as antimicrobial agents. These metals act as iron mimics in vivo and can exert antimicrobial activity while displaying low systemic toxicity in humans. The project aims to exploit this, and the inability of microbes to easily develop resistance towards metals, to combat bacteria for which modern drugs are rapid ....Combating Antimicrobial Resistance with Bismuth, Gallium and Indium. This research project focuses on the design, development, and application of new bismuth, gallium and indium compounds as antimicrobial agents. These metals act as iron mimics in vivo and can exert antimicrobial activity while displaying low systemic toxicity in humans. The project aims to exploit this, and the inability of microbes to easily develop resistance towards metals, to combat bacteria for which modern drugs are rapidly becoming ineffective, as highlighted in the WHO and US Centre for Disease Control list of critical and priority pathogens. The intended outcome is that efficacy will be driven through advances in synthetic and structural chemistry, discovering the mode of action, and creating anti-infective coatings and hydrogels.Read moreRead less
Flexible molecular crystals: single crystals that bend, stretch and twist. This project aims to thoroughly quantify the elastic flexibility of a suite of metal-organic molecular crystals. Since antiquity, crystalline materials have been thought to be brittle and inflexible. Crystals can, in fact, display appreciable, even remarkable, elasticity. Some crystals can bend, stretch and twist. The influence that the molecules, and their arrangements in crystals, have on the extent of elasticity will b ....Flexible molecular crystals: single crystals that bend, stretch and twist. This project aims to thoroughly quantify the elastic flexibility of a suite of metal-organic molecular crystals. Since antiquity, crystalline materials have been thought to be brittle and inflexible. Crystals can, in fact, display appreciable, even remarkable, elasticity. Some crystals can bend, stretch and twist. The influence that the molecules, and their arrangements in crystals, have on the extent of elasticity will be determined along with molecular-scale mechanisms for contortion. This information will be used to design new crystals with predictable and tunable elasticity for potential applications previously considered impossible for crystalline materials.Read moreRead less
Australian Laureate Fellowships - Grant ID: FL170100014
Funder
Australian Research Council
Funding Amount
$3,275,680.00
Summary
Light-Induced chemical modularity: a new frontier in macromolecular design. This project aims to develop powerful light-driven chemistries for the modular construction of advanced macromolecular materials. The expected outcome is a versatile, light-based precision macromolecular synthetic technology platform, enabling critical advances in soft matter material design and synthesis, ranging from selectivity control of chemical reactions and information-coded and biomimetic light-responsive macromo ....Light-Induced chemical modularity: a new frontier in macromolecular design. This project aims to develop powerful light-driven chemistries for the modular construction of advanced macromolecular materials. The expected outcome is a versatile, light-based precision macromolecular synthetic technology platform, enabling critical advances in soft matter material design and synthesis, ranging from selectivity control of chemical reactions and information-coded and biomimetic light-responsive macromolecules to advanced functional photoresists for 3D laser lithography as well as materials that self-report structural transformations by light or are reprogrammable in their properties by photonic fields. Harnessing the power of light as a precision tool for the construction of advanced macromolecular materials will provide technology outcomes for Australian manufacturing industries from electronics to health. This includes laser-driven 3D printing technology at the nano-level, light-adaptive smart reprogrammable coatings and materials, synthetic proteins responsive to light as well as tailor-made single cell niches.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE200100136
Funder
Australian Research Council
Funding Amount
$1,100,000.00
Summary
High Performance Solid State NMR Spectroscopy for Materials Research. The project will support research in a diverse set of fields such as biomedical engineering catalysis, energy storage and waste recovery, with cutting edge next-generation solid state (400 MHz) nuclear magnetic resonance capabilities and research expertise. The system enabling high sensitivity, high throughput analysis over extended temperature range will enable addressing of fundamental questions regarding the structure-prope ....High Performance Solid State NMR Spectroscopy for Materials Research. The project will support research in a diverse set of fields such as biomedical engineering catalysis, energy storage and waste recovery, with cutting edge next-generation solid state (400 MHz) nuclear magnetic resonance capabilities and research expertise. The system enabling high sensitivity, high throughput analysis over extended temperature range will enable addressing of fundamental questions regarding the structure-property relationships of advanced functional materials. Accessible to a wide user base in fundamental and applied research, in medicine, energy, catalysis and recycling of waste, the project will extend the current facilities to develop Sydney as regional centre for advanced solid state nuclear magnetic resonance analysis.Read moreRead less
Nanofluid stickiness will transform the Energy and Biotechnology Industries. This project aims to determine how minuscule particles behave on surfaces with different nano-architecture. Modern technologies already use nanodecorated materials to lubricate engines or capture tumour cells. Yet, their potential in applications for sustainable catalysis, gas treatment or water splitting cannot be realised until we understand how nano-objects adsorb to surfaces with features of comparable size. The exp ....Nanofluid stickiness will transform the Energy and Biotechnology Industries. This project aims to determine how minuscule particles behave on surfaces with different nano-architecture. Modern technologies already use nanodecorated materials to lubricate engines or capture tumour cells. Yet, their potential in applications for sustainable catalysis, gas treatment or water splitting cannot be realised until we understand how nano-objects adsorb to surfaces with features of comparable size. The expected outcomes include new methods, models and a workable map of protein adsorption allowing us to 1) create advanced substrates for targeted applications and 2) understand existing phenomenon governed by naturally occurring nanoroughness. It will benefit manufacturing in fields ranging from biology to energy production.Read moreRead less
2D nanomaterial heterostructures for photocatalytic hydrogen production. This project aims to develop two-dimensional (2D) nanomaterial heterostructures as photocatalysts for hydrogen production from the liquid carrier of methanol. In addition to transformational photocatalytic technology to utilise Australian raw resources, this project expects to generate new knowledge in the areas of photochemistry, materials science and nanotechnology. These should not only expand the applications of 2D nano ....2D nanomaterial heterostructures for photocatalytic hydrogen production. This project aims to develop two-dimensional (2D) nanomaterial heterostructures as photocatalysts for hydrogen production from the liquid carrier of methanol. In addition to transformational photocatalytic technology to utilise Australian raw resources, this project expects to generate new knowledge in the areas of photochemistry, materials science and nanotechnology. These should not only expand the applications of 2D nanomaterials to a new domain of photocatalysts, but also may eventually lead to new industry advances in 2D nanomaterials for a ‘hydrogen economy’. Read moreRead less
Deciphering interactions of conducting polymers in agricultural soils. The project aims to improve agricultural efficiency, productivity and yield by advancing the understanding of polymer materials interacting with fertiliser. This project will test the key assumptions behind a new sensor for real-time in-ground monitoring of fertiliser. The expected outcome from this is the rapid synthesis of conducting polymers for stable sensing of fertiliser in a range of soil types and conditions. This sho ....Deciphering interactions of conducting polymers in agricultural soils. The project aims to improve agricultural efficiency, productivity and yield by advancing the understanding of polymer materials interacting with fertiliser. This project will test the key assumptions behind a new sensor for real-time in-ground monitoring of fertiliser. The expected outcome from this is the rapid synthesis of conducting polymers for stable sensing of fertiliser in a range of soil types and conditions. This should provide the pathway to a world first real-time in-ground fertiliser sensor, providing benefit for the sensor manufacturers, farmers, consumers and the environment.Read moreRead less
Next-generation solid-state batteries to drive an automotive revolution. This project seeks to design and fabricate new solid-state silicon electrodes for advanced high energy, high stability lithium batteries. It is anticipated that this project will generate new knowledge in the area of battery electrode materials through an innovative combination of a soft plastic crystal electrolyte with a highly conductive glass ceramic electrolyte. Expected outcomes of this project include a greater unders ....Next-generation solid-state batteries to drive an automotive revolution. This project seeks to design and fabricate new solid-state silicon electrodes for advanced high energy, high stability lithium batteries. It is anticipated that this project will generate new knowledge in the area of battery electrode materials through an innovative combination of a soft plastic crystal electrolyte with a highly conductive glass ceramic electrolyte. Expected outcomes of this project include a greater understanding of electrolyte properties and an increase in the electrode cycle stability. This should provide significant benefits, such as the development of a new high capacity battery to promote the uptake of electric vehicles and lower Australia's carbon footprint.Read moreRead less
Biomimetic surface coatings for drag and fouling reduction. This project aims to provide new insights into liquid flow and adsorption at liquid/solid and liquid/liquid interfaces, by using a combination of theoretical predictions, nanoscale techniques and nanofabrication approaches. Expected outcomes are the development of liquid-repellent slippery surface coatings that reduce hydrodynamic drag and inhibit marine fouling. This will benefit the fields of advanced manufacturing and smart coatings, ....Biomimetic surface coatings for drag and fouling reduction. This project aims to provide new insights into liquid flow and adsorption at liquid/solid and liquid/liquid interfaces, by using a combination of theoretical predictions, nanoscale techniques and nanofabrication approaches. Expected outcomes are the development of liquid-repellent slippery surface coatings that reduce hydrodynamic drag and inhibit marine fouling. This will benefit the fields of advanced manufacturing and smart coatings, and will underpin a wide range of energy efficient processes and products. Slippery coatings will solve urgent environmental problems of social value by improving the energy and chemical efficiency in fluid flow, heat transfer, secondary oil recovery, microfluidics, and anti-fouling.Read moreRead less
Understand ion-specific effects under nanoconfinement by multiscale models. Different types of ions with the same charge can behave distinctively in many ionic applications. This so-called ion-specific effect is essential to ion separation, ion sensing, electrochemical energy storage, chemical and biomedical processes and many other industrial applications. Confining ions in nanopores and modulating them via surface electric potential can give rise to new ion-specific effects, enabling novel app ....Understand ion-specific effects under nanoconfinement by multiscale models. Different types of ions with the same charge can behave distinctively in many ionic applications. This so-called ion-specific effect is essential to ion separation, ion sensing, electrochemical energy storage, chemical and biomedical processes and many other industrial applications. Confining ions in nanopores and modulating them via surface electric potential can give rise to new ion-specific effects, enabling novel applications. Capitalising on our recent experimental discoveries, this project aims to integrate new multiscale models to understand ion-specific effects in electroconductive nanoporous materials. The new models will be used to quantitatively predict ion-specific effects in supercapacitor design.Read moreRead less