New Biomimetic Nanostructured Coatings for Hip Implants. Over 30,000 hip implants operations take place in Australia each year, due largely to a significant and growing proportion of the population suffering from conditions such as osteoporosis. The coating on the implants, required to cause good bone ingrowth and adhesion between bone and implant, is far from perfect. We propose to spray coatings which mimic the structure of bone, and thus offer improved mechanical properties such as appropriat ....New Biomimetic Nanostructured Coatings for Hip Implants. Over 30,000 hip implants operations take place in Australia each year, due largely to a significant and growing proportion of the population suffering from conditions such as osteoporosis. The coating on the implants, required to cause good bone ingrowth and adhesion between bone and implant, is far from perfect. We propose to spray coatings which mimic the structure of bone, and thus offer improved mechanical properties such as appropriate rigidity and toughness, and stimulate better bone growth at the interface. In this way the implant should be much longer lasting and the need for undesirable revision surgery reduced. The processing technique proposed could also be a useful platform coating technology in a number of other industries.Read moreRead less
New Types of Biomimetic Nanostructured Adhesives. Adhesives are one of the main ways in which we join materials, and have many advantages over other methods of joining. In this work we will make a new class of adhesive using nanotechnology that attempts to copy the very fine-haired feet of animals such as geckos who can stick to almost any surface, under most conditions. We will make these adhesives over large surface areas, and thus they will have commercial possibilities in a range of high tec ....New Types of Biomimetic Nanostructured Adhesives. Adhesives are one of the main ways in which we join materials, and have many advantages over other methods of joining. In this work we will make a new class of adhesive using nanotechnology that attempts to copy the very fine-haired feet of animals such as geckos who can stick to almost any surface, under most conditions. We will make these adhesives over large surface areas, and thus they will have commercial possibilities in a range of high technology industries, as well as in harsh environments. Because we will be able to manipulate the structure and observe property changes, it should also give us a greater insight into the adhesion mechanisms used by many small animals and bugs.Read moreRead less
Novel Tough Polymer Composites. Advanced composites are used in high value-added applications such as computer chip packaging and aerospace applications. In these applications epoxy systems are used despite their inherent brittleness. Much research has focused on toughening epoxy systems, but most tougheners cause a reduction in processing or material properties. This project focuses on developing novel epoxy tougheners during the polymerisation of the epoxy-based composite. Specifically we will ....Novel Tough Polymer Composites. Advanced composites are used in high value-added applications such as computer chip packaging and aerospace applications. In these applications epoxy systems are used despite their inherent brittleness. Much research has focused on toughening epoxy systems, but most tougheners cause a reduction in processing or material properties. This project focuses on developing novel epoxy tougheners during the polymerisation of the epoxy-based composite. Specifically we will use novel hyperbranched [star-like] polymers that have excellent processing properties, high reactivity for structure control and the ability to control toughening at the molecular and macroscopic level to produce novel technology for advanced composites.
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Molecular modelling of the structure and mechanical properties of clay-based polymer nanocomposites. Nanotechnology is one of the most rapidly growing areas in the 21st century. Its world market is expected to reach US$2.6 trillions in 2014, valued at 15% of global manufacturing output. The use of clay nanofillers as polymer reinforcement is an emerging cutting-edge research and of paramount importance in Australia in view of its heavy dependence on mineral industries. The project will tackle th ....Molecular modelling of the structure and mechanical properties of clay-based polymer nanocomposites. Nanotechnology is one of the most rapidly growing areas in the 21st century. Its world market is expected to reach US$2.6 trillions in 2014, valued at 15% of global manufacturing output. The use of clay nanofillers as polymer reinforcement is an emerging cutting-edge research and of paramount importance in Australia in view of its heavy dependence on mineral industries. The project will tackle the core problems in this field. The research outcomes will lead to highly value-added mineral products and better process control. Furthermore, the application of polymer nanocomposites in automotive and packaging industries will significantly decrease energy consumption and CO2 emission, and increase the shelf-life for food and beverage. Read moreRead less
Charge-driven self-assembly of nanocomposites of ionic polymers and oxide nanoparticles. This project addresses the materials needs in platform technologies for more efficient and cleaner means of generating energy and utilising energy. It also aims at better catalysts for cleaner chemical processes. The novel nanocomposites with significantly increased active ionic sites and higher ionic conductivity, and better activity in catalysis will lead to possible new breakthroughs in technologies for e ....Charge-driven self-assembly of nanocomposites of ionic polymers and oxide nanoparticles. This project addresses the materials needs in platform technologies for more efficient and cleaner means of generating energy and utilising energy. It also aims at better catalysts for cleaner chemical processes. The novel nanocomposites with significantly increased active ionic sites and higher ionic conductivity, and better activity in catalysis will lead to possible new breakthroughs in technologies for energy, environmental and self-cleaning materials. The fabrication approach developed are also applicable to other functional nanomaterials, providing new opportunities for innovative nanotechnology to clearer and greener chemical and energy industries.
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The development of super-toughened epoxies using a novel nanomaterial. Epoxy resins are widely used as structural adhesives and coatings in engineering structures. This project will address the problem of the intrinsic brittleness of epoxy by making it significantly tougher with superior performance and cost-effectiveness. Our technology for producing super-toughened epoxy will lead to a wide range of applications for new and existing products in the construction, automotive, aerospace, adhesive ....The development of super-toughened epoxies using a novel nanomaterial. Epoxy resins are widely used as structural adhesives and coatings in engineering structures. This project will address the problem of the intrinsic brittleness of epoxy by making it significantly tougher with superior performance and cost-effectiveness. Our technology for producing super-toughened epoxy will lead to a wide range of applications for new and existing products in the construction, automotive, aerospace, adhesive and microelectronics industries.Read moreRead less
Single molecule actuators. The study of actuation processes in single molecules will lead to the development of improved advanced materials for Australian industry and, ultimately, to the more futuristic and exciting nanotechnologies. The research will improve our understanding of how polymer artificial muscles function, so that these materials can be further developed to meet the demand from industry. Applications include biomedical devices, robotic applicators and various machine parts. In ....Single molecule actuators. The study of actuation processes in single molecules will lead to the development of improved advanced materials for Australian industry and, ultimately, to the more futuristic and exciting nanotechnologies. The research will improve our understanding of how polymer artificial muscles function, so that these materials can be further developed to meet the demand from industry. Applications include biomedical devices, robotic applicators and various machine parts. In addition, the research will also contribute to one of the greatest promises of nanotechnology: the development of molecular machines. We will demonstrate the mechanical forces and movements possible from single molecules so that the design of useful nano-machines can begin.Read moreRead less
Mimicking the perivascular niche with boronolectin-based biomaterials. This project aims to address roadblocks in perivascular stem cell manufacturing by discovering novel mechanisms and materials that improve cell quality outcomes during extended culture. An innovative, interdisciplinary approach to biomaterials discovery, combining live cell-based screening of cell surface glycans, bio-inspired materials design and synthesis, and niche mimicry, will enable the discovery of cell surface glycan- ....Mimicking the perivascular niche with boronolectin-based biomaterials. This project aims to address roadblocks in perivascular stem cell manufacturing by discovering novel mechanisms and materials that improve cell quality outcomes during extended culture. An innovative, interdisciplinary approach to biomaterials discovery, combining live cell-based screening of cell surface glycans, bio-inspired materials design and synthesis, and niche mimicry, will enable the discovery of cell surface glycan-mediated interactions that support long-term expansion and potency maintenance, and synthetic biomaterials that can mimic them. Significant benefits for stem cell researchers, manufacturers and end users are expected from the project and the application of this scalable biomaterial platform.Read moreRead less
Self-reinforced biopolymer composites. This project will pioneer high performance and biodegradable composites using self-reinforced biopolymer composites. Composites can have poor properties due to interfacial issues, and this reduces their performance. By producing a fully self-reinforced (where the fibre and the polymer are the same type of polymer) polymer composites, the project will develop a way to improve properties, increase the use of biobased materials, and improve recyclability and b ....Self-reinforced biopolymer composites. This project will pioneer high performance and biodegradable composites using self-reinforced biopolymer composites. Composites can have poor properties due to interfacial issues, and this reduces their performance. By producing a fully self-reinforced (where the fibre and the polymer are the same type of polymer) polymer composites, the project will develop a way to improve properties, increase the use of biobased materials, and improve recyclability and biodegradability. Outcomes include greater understanding of design of self-reinforced biopolymer composites structure, processing and properties. This will produce opportunities for high performance biobased composite manufacturing and a growing circular plastics economy for Australia.Read moreRead less
Fundamental studies in extensional rheology of polymers and biomacromolecules. Long molecules such as polymers, DNA and other biopolymers are of significant practical and fundamental interest. The behaviour of such polymers in extensional or stretching flows and the consequent stresses generated can be measured as a result of advances in instrumentation pioneered at Monash University. This research program builds on this foundation to understand the effects of molecular architecture on the prope ....Fundamental studies in extensional rheology of polymers and biomacromolecules. Long molecules such as polymers, DNA and other biopolymers are of significant practical and fundamental interest. The behaviour of such polymers in extensional or stretching flows and the consequent stresses generated can be measured as a result of advances in instrumentation pioneered at Monash University. This research program builds on this foundation to understand the effects of molecular architecture on the properties of macromolecules and to rigorously test several innovative theoretical concepts that have been advanced over the last 20 years. Such knowledge allows the tailoring of polymer shape to their end use and permits the design of novel polymers.Read moreRead less