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
Flow process and visible-light driven reactions for polymer manufacturing. This project aims to develop rapid, scalable light-driven continuous flow processing techniques that allow the production of value-added synthetic polymers that cannot be achieved by existing technologies. The project will take advantage of the spatio-temporal control of the light mediated polymerisation with flow process to achieve control over the primary structure, the sequential arrangement of monomer units in a polym ....Flow process and visible-light driven reactions for polymer manufacturing. This project aims to develop rapid, scalable light-driven continuous flow processing techniques that allow the production of value-added synthetic polymers that cannot be achieved by existing technologies. The project will take advantage of the spatio-temporal control of the light mediated polymerisation with flow process to achieve control over the primary structure, the sequential arrangement of monomer units in a polymer chain and the molecular weight distribution. The project will result in the preparation of functional polymers containing a specific arrangement of monomers in the polymer chain and a precise distribution of polymer chains. The development of such process will result in the development of advanced materials.Read moreRead less
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
Hybrid photocatalytic nanomaterials for water purification. This project aims to synthesise and characterise a range of porous photocatalytic materials (materials that absorb light to catalyse a reaction), and to establish high-throughput processes to simultaneously test the effectiveness of multiple photocatalytic materials. This interdisciplinary project expects to develop two new techniques that will lead to faster materials optimisation of materials that breakdown organic pollutants in water ....Hybrid photocatalytic nanomaterials for water purification. This project aims to synthesise and characterise a range of porous photocatalytic materials (materials that absorb light to catalyse a reaction), and to establish high-throughput processes to simultaneously test the effectiveness of multiple photocatalytic materials. This interdisciplinary project expects to develop two new techniques that will lead to faster materials optimisation of materials that breakdown organic pollutants in water under light irradiation. The intended outcomes include the production of industrially relevant photocatalysts and building capability in Australia to decrease photocatalytic testing time and cost. This should provide significant benefits to industry and the environment, and have an impact on human health.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.
Multifunctional 2D materials for sustainable energy applications. This project seeks to explore the great potential of novel graphene-like two dimensional (2-D) materials for energy applications. 2-D materials, which possess atomic or molecular thickness and infinite planar lengths, are regarded as a building block for many applications due to their unique nanostructures, electronic and mechanical properties. This project is focused on the design and exploration of layered two-dimensional artifi ....Multifunctional 2D materials for sustainable energy applications. This project seeks to explore the great potential of novel graphene-like two dimensional (2-D) materials for energy applications. 2-D materials, which possess atomic or molecular thickness and infinite planar lengths, are regarded as a building block for many applications due to their unique nanostructures, electronic and mechanical properties. This project is focused on the design and exploration of layered two-dimensional artificial graphene and graphene analogues with ‘on-demand’ properties to exploit advanced energy applications. There is now a pressing need to integrate graphene sheets into multidimensional and multifunctional systems with spatially well-defined configurations, and integrated systems with a controllable structure and predictable performance. Project outcomes may lead to next-generation devices in energy storage and other applications.Read moreRead less
Impact of Biological Coatings on Nanoparticle–Immune Cell Interactions. Nanomaterials exposed to biological environments such as blood or lymph fluids rapidly adsorb a layer of biomolecules on their surface, forming a biomolecular corona, and profoundly altering their properties. This project aims to resolve the influence of biomolecular coronas on nanoparticle–immune cell interactions by combining particle engineering, immunology, proteomics and bioinformatic analysis. The project expected outc ....Impact of Biological Coatings on Nanoparticle–Immune Cell Interactions. Nanomaterials exposed to biological environments such as blood or lymph fluids rapidly adsorb a layer of biomolecules on their surface, forming a biomolecular corona, and profoundly altering their properties. This project aims to resolve the influence of biomolecular coronas on nanoparticle–immune cell interactions by combining particle engineering, immunology, proteomics and bioinformatic analysis. The project expected outcomes are to generate new knowledge in nanomaterial–immune cell behaviour and design principles for nanoparticles with prospective applications in the agricultural, veterinary and biomedical sectors.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