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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
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100169
Funder
Australian Research Council
Funding Amount
$300,000.00
Summary
Ultraviolet, visible and infrared spectroscopic ellipsometers for advanced materials and device characterisation. The ellipsometers at this facility will enable optical characterisation of several advanced materials in the wide spectral range of 250 nanometres - 30 micrometres. As well as refractive index and thickness measurement, they will provide absorption spectroscopy which will allow assessment of novel glasses and surface functionalisation approaches for the optimisation of new sensing te ....Ultraviolet, visible and infrared spectroscopic ellipsometers for advanced materials and device characterisation. The ellipsometers at this facility will enable optical characterisation of several advanced materials in the wide spectral range of 250 nanometres - 30 micrometres. As well as refractive index and thickness measurement, they will provide absorption spectroscopy which will allow assessment of novel glasses and surface functionalisation approaches for the optimisation of new sensing technologies.Read moreRead less
Advanced macromolecular engineering: novel approaches to self-directed assembly and vesicle formation. The aim of this project is to develop new approaches in nanotechnology for the preparation of well-defined polymeric particles. The research will result in the development of new methodology which has the potential to impact areas of commercial interest including those in the health-care sector.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE120100004
Funder
Australian Research Council
Funding Amount
$470,000.00
Summary
Thin film processing cluster: precise synthesis and nano-patterning of functional coatings. This facility will allow Australian researchers to create advanced functional materials with unprecedented control over material configurations and near atomic scale precision in dimensions. This will enable significant advances in high speed photonics and electronics, health and environment monitoring, and micro-energy sources.
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
New stimuli-responsive polymer membranes using graphene as a multifunctional scaffold. Membranes are used in a range of applications to filter liquids and gases and increasingly must be able to be activated by stimuli such as temperature, pH and voltage. We will develop a new type of membrane which is easy to make, is strong and allows the incorporation of a variety of stimuli-responsive polymers within a functional graphene scaffold.
Discovery Early Career Researcher Award - Grant ID: DE130101550
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Functional polymer encapsulation to enhance biological performance of implantable materials. This project will develop biomaterial films from essential oils using a low-cost 'green' technology. Applied to commercial biomaterials, these films will minimise infections and inflammations commonly associated with implants. These films will also enable clinical use of metallic resorbable implants for tissue engineering and function restoration.
Atomized mucoadhesive particles for pulmonary gene delivery. Scientific and technological advances in material science, biotechnology and biomedical devices are poised to revolutionise healthcare and medicine. By using precisely engineered biomaterials in an efficient miniature electronic inhalation device, a mist of inhalable therapeutics can be generated to deliver improved lung healthcare for Australians.
Australian Laureate Fellowships - Grant ID: FL180100029
Funder
Australian Research Council
Funding Amount
$2,545,000.00
Summary
Nanoionics: Engineering ion transport with two-dimensional materials. This project aims to use graphene and other emerging two-dimensional materials to investigate and manipulate ion transport in nanoscale channels. Nanoionics focuses on understanding ions for transport and storage in nanoscale systems, central to numerous technologies related to water, energy and biomedicine. The project will provide sophisticated methods for revolutionary technological innovations to solve problems in several ....Nanoionics: Engineering ion transport with two-dimensional materials. This project aims to use graphene and other emerging two-dimensional materials to investigate and manipulate ion transport in nanoscale channels. Nanoionics focuses on understanding ions for transport and storage in nanoscale systems, central to numerous technologies related to water, energy and biomedicine. The project will provide sophisticated methods for revolutionary technological innovations to solve problems in several industries including manufacturing, mining, water management and bioengineering. Providing access to previously unavailable structures and materials, the project will support Australia’s manufacturing sector by transforming established industries with next generation technologies. The project will also build capacity of nanoionics engineers and provide intellectual property for commercialised products.Read moreRead less
Macromolecular Engineering of Functional Metal–Ligand Materials. Materials self-assembled from metal ions and ligands have a range of important applications, including as advanced coatings, adhesives and catalysts. However, these materials have been largely limited to those assembled from naturally occurring ligands such as phenolics, restricting their properties and function. This project aims to greatly expand the range of accessible properties of metal–phenolic materials by combining self-ass ....Macromolecular Engineering of Functional Metal–Ligand Materials. Materials self-assembled from metal ions and ligands have a range of important applications, including as advanced coatings, adhesives and catalysts. However, these materials have been largely limited to those assembled from naturally occurring ligands such as phenolics, restricting their properties and function. This project aims to greatly expand the range of accessible properties of metal–phenolic materials by combining self-assembly with advanced polymer synthesis techniques. The expected outcome of the project is a new class of functional materials applicable as self-healing coatings, nanoadhesives and antimicrobial surfaces, thus underpinning next-generation technologies in materials science and nanotechnology.Read moreRead less