Engineered nanoassmblies for energy conversion. This research will lead to development of clean energy technology that can compete with the traditional energy sources without subsidies, and facilitate long-term solution to the energy crisis and global warming. It will also bring significant benefit to Australian industries and economy and assist achievement of renewable energy target.
Discovery Early Career Researcher Award - Grant ID: DE150100280
Funder
Australian Research Council
Funding Amount
$373,536.00
Summary
Bio-inspired multifunctional inorganic nanostructured interfaces. Learning from nature involves taking ideas from nature and developing novel functional materials. This project aims to design novel bio-inspired multifunctional interfaces to prevent the adherence of crystals and solid particles to surfaces, achieve excellent mechanical resilience, and provide multiple photoresponses, based on a deep understanding of the fundamental physiochemical, mechanical, structural, and optical characteristi ....Bio-inspired multifunctional inorganic nanostructured interfaces. Learning from nature involves taking ideas from nature and developing novel functional materials. This project aims to design novel bio-inspired multifunctional interfaces to prevent the adherence of crystals and solid particles to surfaces, achieve excellent mechanical resilience, and provide multiple photoresponses, based on a deep understanding of the fundamental physiochemical, mechanical, structural, and optical characteristics of natural multifunctional surfaces/interfaces in the target natural species. This project aims to aid in the design of new bio-inspired smart materials and deliver novel technologies for materials synthesis for potential uses in the chemical industry, sustainable energy applications, and agriculture.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100195
Funder
Australian Research Council
Funding Amount
$1,000,000.00
Summary
Field-emission gun transmission electron microscope for the research in nanomaterials, metal alloys and biological sciences. The proposed facility is required by a large range of world-leading research programs in light metals, nanomaterials, fibres and biomaterials. These research programs are strongly supported by automobile, textile, mineral and advanced materials industries that have important roles in the current national economy and local communities. The facility will improve significan ....Field-emission gun transmission electron microscope for the research in nanomaterials, metal alloys and biological sciences. The proposed facility is required by a large range of world-leading research programs in light metals, nanomaterials, fibres and biomaterials. These research programs are strongly supported by automobile, textile, mineral and advanced materials industries that have important roles in the current national economy and local communities. The facility will improve significantly our current research ability and help the creation of new research areas in nanotechnology and energy materials beneficial to clean energy, environmental protections and health care. It is also important equipment for new research student training.Read moreRead less
Structurally Nanoengineered Antimicrobial Polypeptide Particles (SNAPPs). This project aims to develop a new platform technology for the development of antimicrobial agents by combining expertise in polymer science and antimicrobial studies. It aims to develop new nanoengineered particles for combating antibiotic-resistant bacteria, investigate the influence of particle architecture on antibacterial properties, and determine the mechanism of action. This may support the development of antibiotic ....Structurally Nanoengineered Antimicrobial Polypeptide Particles (SNAPPs). This project aims to develop a new platform technology for the development of antimicrobial agents by combining expertise in polymer science and antimicrobial studies. It aims to develop new nanoengineered particles for combating antibiotic-resistant bacteria, investigate the influence of particle architecture on antibacterial properties, and determine the mechanism of action. This may support the development of antibiotic treatments using new polypeptide particles as antibacterial drugs, resulting in advances in nanobiotechnology, polymer therapeutics and advanced materials. The outcomes may revolutionise the synthetic approach to antimicrobial peptides and contribute significantly towards current antibiotic treatments and approaches for advanced antibacterial formulations.Read moreRead less
Engineering drug transportation behaviour in polymeric gel systems. In collaboration with Seagull Technologies, this project aims to engineer, study and mathematically model ultrasound-assisted biomacromolecule transport behaviour within polymeric gel systems, which may be useful in new drug delivery methods. The intended outcome is a novel set of polymeric gel systems, which can reversibly bind a wide variety of drugs (small molecules, nucleic acid based drugs, proteins), in which drug release ....Engineering drug transportation behaviour in polymeric gel systems. In collaboration with Seagull Technologies, this project aims to engineer, study and mathematically model ultrasound-assisted biomacromolecule transport behaviour within polymeric gel systems, which may be useful in new drug delivery methods. The intended outcome is a novel set of polymeric gel systems, which can reversibly bind a wide variety of drugs (small molecules, nucleic acid based drugs, proteins), in which drug release is triggered by an electric potential and drug transport is controlled by means of sonophoresis. The main advantage of drug delivery via sonophoresis is elimination of risks associated with injections such as infection and damage to local tissue, and elimination of patient discomfort, pain and fear.Read moreRead less
Cell facilitated controlled radical polymerisation. This project aims to develop a controlled polymerisation method by combining reversible addition fragmentation chain (RAFT) polymerisation technology and the redox processes within bacterial cells. This polymerisation method will copy biological information in the bacterial cell surface into a growing polymer structure. Variations in the monomer structures and functionality will be used to control the incorporation of cell surface chemistry int ....Cell facilitated controlled radical polymerisation. This project aims to develop a controlled polymerisation method by combining reversible addition fragmentation chain (RAFT) polymerisation technology and the redox processes within bacterial cells. This polymerisation method will copy biological information in the bacterial cell surface into a growing polymer structure. Variations in the monomer structures and functionality will be used to control the incorporation of cell surface chemistry into the new polymer structure. Such cell-enabled controlled polymerisation could advance polymer synthesis resulting in biologically instructed polymer-mimics and new antibacterial agents.Read moreRead less
Precision-Engineered Polymer Nanomaterials. Designing polymer nanoparticles that interact with or mimic biological systems represents a challenge in the field of polymer science. The project will address this challenge to deliver a quantitative and qualitative understanding linking synthetic materials and biological systems. Structurally perfect polymeric dendrimers, prepared using break through synthetic approaches and kinetic and computer modelling, are the ideal structure to introduce this fu ....Precision-Engineered Polymer Nanomaterials. Designing polymer nanoparticles that interact with or mimic biological systems represents a challenge in the field of polymer science. The project will address this challenge to deliver a quantitative and qualitative understanding linking synthetic materials and biological systems. Structurally perfect polymeric dendrimers, prepared using break through synthetic approaches and kinetic and computer modelling, are the ideal structure to introduce this function with predictable behaviour. The project will achieve tangible impacts for global communities and industries including the development of biomimetic nanodevices for smart drug delivery devices and peptide mimics.Read moreRead less
ARC Centre of Excellence for Electromaterials Science. The ARC Centre of Excellence for Electromaterials Science (ACES) will create next generation electrochemical devices via the precision assembly of nano/micro dimensional components into macroscopic structures. Through the discovery of new materials and structures, and understanding how spatial arrangement in 3D influences chemical, physical and biological properties, ACES will define the cutting edge of Electromaterials Science. The resultin ....ARC Centre of Excellence for Electromaterials Science. The ARC Centre of Excellence for Electromaterials Science (ACES) will create next generation electrochemical devices via the precision assembly of nano/micro dimensional components into macroscopic structures. Through the discovery of new materials and structures, and understanding how spatial arrangement in 3D influences chemical, physical and biological properties, ACES will define the cutting edge of Electromaterials Science. The resulting technology breakthroughs will have a direct impact on some of today's most challenging global problems in clean energy, synthetic biosystems, diagnostics and soft robotics. National benefit to Australia will be realised through the creation of new manufacturing industries.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