Bespoke nanomaterials for understanding nano-bio interactions under flow. This project aims to develop innovative scalable synthesis techniques to produce polymeric nanomaterials with controlled properties and characterise interactions between nanomaterials and cells under flow conditions. This project expects to generate new knowledge in priority research areas of nanotechnology, polymer chemistry and immunology. The outcome of this project is an original scalable and environmentally friendly t ....Bespoke nanomaterials for understanding nano-bio interactions under flow. This project aims to develop innovative scalable synthesis techniques to produce polymeric nanomaterials with controlled properties and characterise interactions between nanomaterials and cells under flow conditions. This project expects to generate new knowledge in priority research areas of nanotechnology, polymer chemistry and immunology. The outcome of this project is an original scalable and environmentally friendly technology, new knowledge of cell-nanomaterial interactions and new design principles for nanoparticles with potential future applications in drug delivery, immunology and nanomedicine. This project should provide significant benefits to polymer, nanomaterial and pharmaceutical research and industry in Australia.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
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
Precision porous polymer microparticles via integrated flow processes. This project aims at a step-change in functional, porous microparticle manufacture. To achieve this, the project will use precision flow chemistry techniques that will integrate emulsion preparation, microparticle production and chemical functionalisation in one continuous process. The expected outcome of the project is a process for the manufacture of a suite of designer porous polymer microparticles. Expected benefits are d ....Precision porous polymer microparticles via integrated flow processes. This project aims at a step-change in functional, porous microparticle manufacture. To achieve this, the project will use precision flow chemistry techniques that will integrate emulsion preparation, microparticle production and chemical functionalisation in one continuous process. The expected outcome of the project is a process for the manufacture of a suite of designer porous polymer microparticles. Expected benefits are disruptive advances in a number of key technological sectors, including biomedicine, pharmacy, energy and bioprocessing. Platform technology for cartilage tissue engineering has been chosen as an exemplar of the power of precision microparticles.Read moreRead less
Chiral synthetic macromolecules - control of sequence and stereochemistry. This project aims to assemble a library of novel chiral polymers mimicking natural peptides with precisely controlled primary structures using emerging synthetic technologies. A systematic investigation of these synthetic materials will provide an in-depth understanding of how sequence and stereochemistry influence chemical and physical properties. Employing rational design principles, desired functionality could be optim ....Chiral synthetic macromolecules - control of sequence and stereochemistry. This project aims to assemble a library of novel chiral polymers mimicking natural peptides with precisely controlled primary structures using emerging synthetic technologies. A systematic investigation of these synthetic materials will provide an in-depth understanding of how sequence and stereochemistry influence chemical and physical properties. Employing rational design principles, desired functionality could be optimised through the selective modification of polymer structure. These materials should be able to emulate the unique properties and functionality of natural peptides/proteins, making them invaluable for biochemical applications, such as molecular recognition and asymmetric catalysis.Read moreRead less
Bioinspired Ion Transporters for Efficient Energy Conversion and Storage. This project aims to fabricate bioinspired light-driven ion transporters with biological-level active ion transport efficiency for efficient energy conversion and storage. Engineering of artificial membranes with ion-pump-like pore structures, specific ion binding sites and photo-excited molecular gates by an innovative bioinspired approach is expected to generate new knowledge in the field of biomimetic design of artifici ....Bioinspired Ion Transporters for Efficient Energy Conversion and Storage. This project aims to fabricate bioinspired light-driven ion transporters with biological-level active ion transport efficiency for efficient energy conversion and storage. Engineering of artificial membranes with ion-pump-like pore structures, specific ion binding sites and photo-excited molecular gates by an innovative bioinspired approach is expected to generate new knowledge in the field of biomimetic design of artificial ion-transporter membranes and bring new technologies to applications such as in solar energy harvesting, osmotic power generation, ionic batteries, and ionic circuits. The proposed research should provide significant benefits such as new energy conversion and storage technologies for Australian manufacturing industry.Read moreRead less
Nano-fibrous structure for high-performance organic photovoltaic thin films. This project aims to create nano-fibrous active thin films with high charge mobility for organic photovoltaic (OPV) devices, using a method inspired by molecular gelation. The significance of this project is that it addresses a major bottleneck, i.e. poor charge generation and transport, that limits the efficiency of OPV devices. The outcomes will provide insights into the crucial factors that affect the self-assembly o ....Nano-fibrous structure for high-performance organic photovoltaic thin films. This project aims to create nano-fibrous active thin films with high charge mobility for organic photovoltaic (OPV) devices, using a method inspired by molecular gelation. The significance of this project is that it addresses a major bottleneck, i.e. poor charge generation and transport, that limits the efficiency of OPV devices. The outcomes will provide insights into the crucial factors that affect the self-assembly of organic semiconducting materials, and the influences of nano-fibrous structure on the charge mobility and efficiency of an OPV device. The outcomes will greatly facilitate the development of highly efficient, lightweight and low-cost solar energy harvesting devices to reduce our carbon footprint.Read moreRead less
Industrial Transformation Training Centres - Grant ID: IC170100020
Funder
Australian Research Council
Funding Amount
$3,279,502.00
Summary
ARC Training Centre for the Chemical Industries . The ARC Training Centre for the Chemical Industries will foster a world-class environment of transformative innovative research in Australia’s chemical and advanced manufacturing industry through sustained partnerships with universities. The Centre establish a new industry-led HDR graduate program. The research activities of the Centre aim to improve chemical analytical and manufacturing capabilities, new biopharmaceuticals, enhanced global compe ....ARC Training Centre for the Chemical Industries . The ARC Training Centre for the Chemical Industries will foster a world-class environment of transformative innovative research in Australia’s chemical and advanced manufacturing industry through sustained partnerships with universities. The Centre establish a new industry-led HDR graduate program. The research activities of the Centre aim to improve chemical analytical and manufacturing capabilities, new biopharmaceuticals, enhanced global competitive advantages, and long-term growth and intellectual property development in the chemistry industry. Other national benefits include up-skilled, workplace-ready graduates with experience in conducting industry-focused research.Read moreRead less