Nanostructured anticorrosive coating for wave energy conversion module. The project will develop new high performance anticorrosion coatings for metal structures, such as a Waverider- a patented wave energy conversion module. It will deliver a strong intellectual property position in the frontier anti-corrosion technology to Australian Industry and train young scientists in the emerging and multidisciplinary field of research.
Nanogels: Next Generation Polymeric Particles. The existing knowledge in the formation of polymeric networks limits the technological development of polymer materials. This project will introduce new polymeric particles, called nanogels to open a new area in new polymeric architecture research. A number of new structures based on the nanogels will be developed. These new macromolecules will not only bring the polymer science into a new field, it will provide a great opportunity to discover the ....Nanogels: Next Generation Polymeric Particles. The existing knowledge in the formation of polymeric networks limits the technological development of polymer materials. This project will introduce new polymeric particles, called nanogels to open a new area in new polymeric architecture research. A number of new structures based on the nanogels will be developed. These new macromolecules will not only bring the polymer science into a new field, it will provide a great opportunity to discover the next generation of the polymeric products, particularly for application in automotive paint, drug delivery and bio-molecular separations.Read moreRead less
Novel Coatings For Steel. The aim of this project is to design coatings for steel that have high flexibility and high resistance to scatching and hardness. This will be achieved by the introduction of liquid crystalline phases in the coatings. The outcome will be a new generation of steel coatings with novel properties
New Surface Coatings Derived from Renewable Resources. In this project we will develop a novel, efficient cross-linking methodology to generate surface coating and adhesive products from inexpensive, renewable, local, natural feedstocks. Potential economic benefits to Australia include the replacement of imported petrochemical feedstocks with Australian agricultural products, the development of high performance products with the potential for export, and the establishment of an intellectual prop ....New Surface Coatings Derived from Renewable Resources. In this project we will develop a novel, efficient cross-linking methodology to generate surface coating and adhesive products from inexpensive, renewable, local, natural feedstocks. Potential economic benefits to Australia include the replacement of imported petrochemical feedstocks with Australian agricultural products, the development of high performance products with the potential for export, and the establishment of an intellectual property portfolio that will lead to opportunities for licensing internationally.Read moreRead less
Environmentally responsive clean coatings. Nature makes use of a range of fascinating surface properties, such as the leaves of the Lotus plant which stay clean even in dirty environments. In this project we will explore the molecular properties of novel polymer coated surfaces that-similar to some natural surfaces-can adapt to changing environmental stimuli and be resistant to contamination. Specifically, we aim to develop self-cleaning polymer coatings which can reversibly switch from wettab ....Environmentally responsive clean coatings. Nature makes use of a range of fascinating surface properties, such as the leaves of the Lotus plant which stay clean even in dirty environments. In this project we will explore the molecular properties of novel polymer coated surfaces that-similar to some natural surfaces-can adapt to changing environmental stimuli and be resistant to contamination. Specifically, we aim to develop self-cleaning polymer coatings which can reversibly switch from wettable to non-wettable with changing temperature and humidity. These self-cleaning polymer surfaces with environmentally responsive properties will add value to pre-painted steel products and other coatings.Read moreRead less
Wet Particulate Materials - Flow or Fracture? Most advanced materials are produced from starting materials in the form of fine particles. Powders, especially in ceramic engineering, are first processed wet into near-final shape. Improved understanding of the fracture of particle networks is critical in order to process nano-sized advanced ceramic materials for use in solar energy harvesting and extreme heat engine applications as well as minimising drying cracks in paints and coatings. The resea ....Wet Particulate Materials - Flow or Fracture? Most advanced materials are produced from starting materials in the form of fine particles. Powders, especially in ceramic engineering, are first processed wet into near-final shape. Improved understanding of the fracture of particle networks is critical in order to process nano-sized advanced ceramic materials for use in solar energy harvesting and extreme heat engine applications as well as minimising drying cracks in paints and coatings. The research aims to identify the fundamental link between particle network strength and structure and the fracture of wet powder bodies. The microscopic mechanisms that control the behaviour will be investigated with a particular focus on toughening mechanisms including the influence of plasticity.Read moreRead less
Nano-scale Modification of Paint Surfaces for Contamination Resistance. The main aim of this work is to develop a process to produce a dirt resistant paint surface. Dirt resistance is an important characteristic of prepainted steel sheets often used in architectural situations where dirt build-up is unsightly. To develop the process it will be necessary to understand the mechanism of dirt adhesion to paints and the modes of operation of current dirt resistant processes. In addition work will be ....Nano-scale Modification of Paint Surfaces for Contamination Resistance. The main aim of this work is to develop a process to produce a dirt resistant paint surface. Dirt resistance is an important characteristic of prepainted steel sheets often used in architectural situations where dirt build-up is unsightly. To develop the process it will be necessary to understand the mechanism of dirt adhesion to paints and the modes of operation of current dirt resistant processes. In addition work will be required on the rate of surface segregation of additives to the paint solution. We propose to combine experimental and theoretical modelling approaches to obtain a fundamentally sound practical solution.Read moreRead less
Novel Nano Particles for Advanced Automotive and Industrial Coatings. In conjunction with our industrial partner (DuPont Australia), this project will develop a new generation of automotive and industrial coatings. The technology developed from this project can integrate into the existing system. The new coatings will be environmentally friendly and will make a significant contribution to solve the emission issue of volatile organic compound (VOC) faced by the industry. The novel nano particles ....Novel Nano Particles for Advanced Automotive and Industrial Coatings. In conjunction with our industrial partner (DuPont Australia), this project will develop a new generation of automotive and industrial coatings. The technology developed from this project can integrate into the existing system. The new coatings will be environmentally friendly and will make a significant contribution to solve the emission issue of volatile organic compound (VOC) faced by the industry. The novel nano particles developed from this project will provide unique properties for automotive paint and can be commercialized at an acceptable price. The science involved in this project represents the cutting edge of world leading technology and will bring polymer science into a new field.Read moreRead less
Characterization of star nanogels by advanced transmission electron microscopy. This project will provide an excellent opportunity to combine research expertise from The Polymer Science Group at The University of Melbourne and The Polymer Morphology Group at North Carolina State University (NCSU) to develop and characterize novel star nanogels with unique macromolecular architectures. The success of the project will reveal the absolute structures of these molecules and the proposed studies are b ....Characterization of star nanogels by advanced transmission electron microscopy. This project will provide an excellent opportunity to combine research expertise from The Polymer Science Group at The University of Melbourne and The Polymer Morphology Group at North Carolina State University (NCSU) to develop and characterize novel star nanogels with unique macromolecular architectures. The success of the project will reveal the absolute structures of these molecules and the proposed studies are both intellectually challenging in the cutting-edge of leading research in the field and important to provide vital information for the design of new structures of these new materials for their application in many areas, such as drug delivery, new membrane formation, advance high density memory chips and possibly the next generation of automotive coating.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