Next generation core-shell materials based on biomolecular dual-templating. This project aims to discover and develop new methods and knowledge for the precision engineering of next-generation core-shell materials using sustainable biomolecular dual-templating processes. This research builds on a recent breakthrough - emulsion and biomimetic dual-templating technology for facile preparation of silica capsules, and is expected to revolutionise current approaches for making core-shell materials. S ....Next generation core-shell materials based on biomolecular dual-templating. This project aims to discover and develop new methods and knowledge for the precision engineering of next-generation core-shell materials using sustainable biomolecular dual-templating processes. This research builds on a recent breakthrough - emulsion and biomimetic dual-templating technology for facile preparation of silica capsules, and is expected to revolutionise current approaches for making core-shell materials. Significant outcomes are expected to be achieved through building fundamental understanding around this breakthrough, including new concepts for hierarchical nanomaterials based on biomolecular design, new molecular and engineering design rules for core-shell materials, and novel materials for applications in sustained release and delivery systems.Read moreRead less
Precision-engineered hybrid core-shell materials . This project aims to develop new platform technologies for making nanostructured hybrid core-shell materials with exceptionally high drug loading and programmed release. Building on this research team's recent breakthrough in the precision engineering of core-shell materials, this research will revolutionise current approaches for making drug-loaded polymer and inorganic particles. Significant outcomes will include a novel sequential nanoprecipi ....Precision-engineered hybrid core-shell materials . This project aims to develop new platform technologies for making nanostructured hybrid core-shell materials with exceptionally high drug loading and programmed release. Building on this research team's recent breakthrough in the precision engineering of core-shell materials, this research will revolutionise current approaches for making drug-loaded polymer and inorganic particles. Significant outcomes will include a novel sequential nanoprecipitation platform technology for making drug-core polymer-shell nanoparticles, and a new bio-inspired approach for making hybrid drug-core silica-shell nanocomposites, and new materials for applications in programmed release and delivery systems.Read moreRead less
Mechanical modulation of particle-cell interactions. Mechanical forces play critical roles in many biological processes, but how particle mechanical properties modulate particle-cell interactions remains elusive. This project aims to develop new design principles for engineering nano/micromaterials with tunable mechanical properties for improved cell activation and expansion, and to advance knowledge of the role of particle stiffness in modulating receptor-mediated particle-cell interactions. Ex ....Mechanical modulation of particle-cell interactions. Mechanical forces play critical roles in many biological processes, but how particle mechanical properties modulate particle-cell interactions remains elusive. This project aims to develop new design principles for engineering nano/micromaterials with tunable mechanical properties for improved cell activation and expansion, and to advance knowledge of the role of particle stiffness in modulating receptor-mediated particle-cell interactions. Expected outcomes and benefits include new fundamental understanding of the effect of particle mechanical properties on cell function, new insights into T cell activation and expansion, and new classes of stiffness-tunable fit-for-purpose materials for various applications in cell manufacturing.Read moreRead less
Platform technologies for multifunctional nanocarrier systems. Smart targeted nanocarriers offer new opportunities for drug delivery. This project aims to develop new platforms for reproducibly producing and screening targeted nanocarriers. The platform technologies developed in this project aim to revolutionise current strategies for designing and evaluating drug delivery systems, and will accelerate the clinical translation of targeted drug delivery. This will include a novel one-step microflu ....Platform technologies for multifunctional nanocarrier systems. Smart targeted nanocarriers offer new opportunities for drug delivery. This project aims to develop new platforms for reproducibly producing and screening targeted nanocarriers. The platform technologies developed in this project aim to revolutionise current strategies for designing and evaluating drug delivery systems, and will accelerate the clinical translation of targeted drug delivery. This will include a novel one-step microfluidic platform technology for reproducibly producing targeted polymer nanocarriers having systematically varied properties, a dual-templating method for making targeted silica nanocapsules and new design of in vivo-mimicking 'Tissue Chips' for screening and evaluating the nanocarriers.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
Develop Catalyst Materials for Future Fuels by Operando Computation. This project aims to design catalyst materials for the production of future fuels (green ammonia, hydrocarbon and alcohol). Using carbon and nitrogen as energy carriers, these fuels are generated from renewable sources such as wind or solar; they are safe, reliable, and possess high energy density. The outcomes include advance in computational electrochemistry to the Opeando level, electrocatalysts design principles with clearl ....Develop Catalyst Materials for Future Fuels by Operando Computation. This project aims to design catalyst materials for the production of future fuels (green ammonia, hydrocarbon and alcohol). Using carbon and nitrogen as energy carriers, these fuels are generated from renewable sources such as wind or solar; they are safe, reliable, and possess high energy density. The outcomes include advance in computational electrochemistry to the Opeando level, electrocatalysts design principles with clearly articulated reaction mechanisms, and candidate materials for experimental validation. Facilitated by advanced computation techniques and reliable catalyst materials design procedure, this project will address the biggest challenge in future fuel generation, which is the lack of efficient catalyst materials. Read moreRead less
Engineered nanoporous materials and composites having hierarchical structures by emulsion templating. The project aims to develop new and flexible emulsion-templated processes capable of constructing novel nanoporous materials with hierarchical structures. The project has the potential to revolutionise current approaches for making porous materials, and the outcomes will enhance Australia's ability in frontier technologies and advanced materials.
Electronic coupling and nanoscale engineering of two-dimensional nanojunctions. This project aims to improve the design of photovoltaic, energy storage, and nanocatalytic devices by using quantum-size tuning, orientation control, strain engineering, and surface modification to manipulate the electronic coupling and charge transfer of two-dimensional nanojunctions. The limitations of and potential environmental damage from fossil-fuel-based energy resources have increased interest in renewable en ....Electronic coupling and nanoscale engineering of two-dimensional nanojunctions. This project aims to improve the design of photovoltaic, energy storage, and nanocatalytic devices by using quantum-size tuning, orientation control, strain engineering, and surface modification to manipulate the electronic coupling and charge transfer of two-dimensional nanojunctions. The limitations of and potential environmental damage from fossil-fuel-based energy resources have increased interest in renewable energy research. The expected outcomes are electron-scale understanding of the tuneable functionalisation of two-dimensional nanojunctions and the design of low-cost and high-efficiency renewable energy devices.Read moreRead less
Catalysts for hydrogen-free ammonia production by electrochemical method. This project aims to realise the next generation of ammonia production under ambient conditions without hydrogen feedstock. Through a combination of theoretical molecular-level understanding and experimental materials engineering, a range of catalysts will be developed under a materials discovery scheme for electrochemical nitrogen reduction to ammonia. These new catalysts, featuring high activity, efficiency, selectivity, ....Catalysts for hydrogen-free ammonia production by electrochemical method. This project aims to realise the next generation of ammonia production under ambient conditions without hydrogen feedstock. Through a combination of theoretical molecular-level understanding and experimental materials engineering, a range of catalysts will be developed under a materials discovery scheme for electrochemical nitrogen reduction to ammonia. These new catalysts, featuring high activity, efficiency, selectivity, and stability, will facilitate an alternative artificial nitrogen fixation technology powered by renewable energies. This technology will enable the production of green fertilisers and provide renewable energy storage, which are key environmental and energy challenges that Australia and the world currently face.Read moreRead less
Engineering nanostructured graphene-based semiconductor photocatalysts. Harnessing solar energy and converting it into useful chemical energy efficiently is the expected outcome of the project. Given the strategic solar-geographical position of Australia, solar photocatalysis is a leading option for utilising our renewable energy resources to applications relating to energy conversion and environmental remediation.