New Strategies for Modelling Polyoxometalates. Polyoxometalates are a versatile class of genuine nanomaterials with remarkable chemical and physical properties and dimensions ranging from tens to tens of thousands of atoms. Designing functional materials which exploit their enormous potential is limited by practical difficulties in their structural characterization and restrictions on our ability to model their behaviour. In this project, we will develop a new strategy for computer modelling of ....New Strategies for Modelling Polyoxometalates. Polyoxometalates are a versatile class of genuine nanomaterials with remarkable chemical and physical properties and dimensions ranging from tens to tens of thousands of atoms. Designing functional materials which exploit their enormous potential is limited by practical difficulties in their structural characterization and restrictions on our ability to model their behaviour. In this project, we will develop a new strategy for computer modelling of polyoxometalates based on the classical molecular mechanics approach and high-level techniques. This novel line of attack will be exploited in the characterization of large and highly substituted derivatives which are key to developing functional materials.Read moreRead less
Degradable hollow microspheres for liver cancer treatment. The expected outcome of this multidisciplinary approach is a controlled drug delivery system for the treatment of liver cancer. We aim to increase the understanding of drug release using polymeric microspheres and the influence of the polymer properties on the release kinetics resulting in the tailored drug release for liver cancer treatment. An indepth knowledge in drug delivery can lead to optimised release kinetics leding to an increa ....Degradable hollow microspheres for liver cancer treatment. The expected outcome of this multidisciplinary approach is a controlled drug delivery system for the treatment of liver cancer. We aim to increase the understanding of drug release using polymeric microspheres and the influence of the polymer properties on the release kinetics resulting in the tailored drug release for liver cancer treatment. An indepth knowledge in drug delivery can lead to optimised release kinetics leding to an increased patient convenience and life prolonging treatments.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0346891
Funder
Australian Research Council
Funding Amount
$200,000.00
Summary
Characterization facilities for new macromolecular architectures. The proposed facility is essential for characterization of the new polymeric architectures such as copolymers for tissue engineering, nanogels for automotive paints and biodegradable polymeric packaging. The facilities include characterizations of (1) molar mass and molecular sizes of novel polymer architectures (MU); (2) viscoelastic mechanical properties of tensile, bending, bulk and flow (RMIT); and (3) thermal properties of c ....Characterization facilities for new macromolecular architectures. The proposed facility is essential for characterization of the new polymeric architectures such as copolymers for tissue engineering, nanogels for automotive paints and biodegradable polymeric packaging. The facilities include characterizations of (1) molar mass and molecular sizes of novel polymer architectures (MU); (2) viscoelastic mechanical properties of tensile, bending, bulk and flow (RMIT); and (3) thermal properties of compositions (CSIRO). These new polymeric architectures cannot be sufficiently characterized by existing facilities. The success of the project will significantly enhance the new macromolecular research and facilitate collaborations. This project also falls within the nano and biomaterials of the Designated Priority area of Research.Read moreRead less
Building advanced polymeric nanotubes for targeted drug delivery. Advanced drug delivery devices have major commercial applications in fighting diseases like cancer and infectious viruses. The success of this project will provide fundamental knowledge for the design of new drug delivery devices based on polymeric nanotubes. The project will also further advance Australia's nano- and bio-technological research and industries. This project will also provide additional benefit for developing contro ....Building advanced polymeric nanotubes for targeted drug delivery. Advanced drug delivery devices have major commercial applications in fighting diseases like cancer and infectious viruses. The success of this project will provide fundamental knowledge for the design of new drug delivery devices based on polymeric nanotubes. The project will also further advance Australia's nano- and bio-technological research and industries. This project will also provide additional benefit for developing controlled release systems in drug delivery and artificial vessels, and improve sensitivity in molecular sensors. The pioneering work proposed will ensure that Australia remains at the forefront of innovative scientific research within the rapidly advancing disciplines of nanotechnology and novel macromolecular design.Read moreRead less
ARC Centre of Excellence in Exciton Science. This Centre aims to manipulate the way light energy is absorbed, transported and transformed in advanced molecular materials. The research programme spans high-throughput computational screening, single molecule photochemistry and ultrafast spectroscopy and embraces innovative outreach and commercial translation activities. The Centre plans to capture the knowledge generated as new intellectual property, materials processing know-how, and through the ....ARC Centre of Excellence in Exciton Science. This Centre aims to manipulate the way light energy is absorbed, transported and transformed in advanced molecular materials. The research programme spans high-throughput computational screening, single molecule photochemistry and ultrafast spectroscopy and embraces innovative outreach and commercial translation activities. The Centre plans to capture the knowledge generated as new intellectual property, materials processing know-how, and through the creation of new employment opportunities. The expected outcomes and benefits include new Australian technologies in solar energy conversion, energy-efficient lighting and displays, security labelling and optical sensor platforms for defence.Read moreRead less
Theoretical and computational approaches to accurately predict the structures of a unique family of circular and knotted proteins. The primary outcome will be a fundamental new knowledge on cyclotide structures and a new protein engineering method to design stabilised proteins. Because cyclotides have significantly higher stabilities than conventional proteins, they have a range of pharmaceutical and agricultural applications. Both fields of use have the potential for very great economic and soc ....Theoretical and computational approaches to accurately predict the structures of a unique family of circular and knotted proteins. The primary outcome will be a fundamental new knowledge on cyclotide structures and a new protein engineering method to design stabilised proteins. Because cyclotides have significantly higher stabilities than conventional proteins, they have a range of pharmaceutical and agricultural applications. Both fields of use have the potential for very great economic and social benefits for Australia. From a pharmaceutical perspective our computing development will greatly facilitate the design of stabilised peptide-based drugs using the cyclotide framework. Such drugs have potential sales of several billion dollars per annum and the royalty returns from successful commercialisation of IP can be substantial.Read moreRead less
Targeted synthesis of porous materials towards gas sorption and separation. Targeted synthesis, using a building block strategy and computational design, is an efficient method for controlled synthesis of porous materials. This project uses this method to synthesise porous materials with permanent functional pores for separating and storing fuels and greenhouse gases, addressing demanding energy and environmental problems.
Advanced adsorbents for gas separations. Efficient purification of natural gas and separation of similarly-sized molecules in gas mixtures is increasingly important in our drive to develop a more sustainable way of living in an energy-constrained world. This project will develop a new class of adsorbents to deliver a level of separation efficiency much higher than that currently in use.
Discovery Early Career Researcher Award - Grant ID: DE180100112
Funder
Australian Research Council
Funding Amount
$348,575.00
Summary
Design and synthesis of new radical and heterometallic magnetic molecules. This project aims to build upon recent advances in developing magnetic molecules for use in electronic devices. The development of new electronic devices based on quantum systems will lead to the development of faster more efficient computers. Magnetic molecules are promising candidates for the data storage components in these systems. Despite the potential of these materials, the temperature at which they operate needs t ....Design and synthesis of new radical and heterometallic magnetic molecules. This project aims to build upon recent advances in developing magnetic molecules for use in electronic devices. The development of new electronic devices based on quantum systems will lead to the development of faster more efficient computers. Magnetic molecules are promising candidates for the data storage components in these systems. Despite the potential of these materials, the temperature at which they operate needs to be increased above that of liquid helium. This project is focused on the development of new magnetic lanthanide molecules with higher working temperatures. The outcomes will provide a greater understanding of how structure impacts on the magnetic properties of the molecule.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