New metal-molecule binding motifs for self-assembled monolayers and nanodevices. The goal of this research is to investigate technologically interesting electronic materials using new molecular assemblies. We explore their application in some fundamental components of molecular electronic systems and anticipate that knowledge gained from our investigations will have significant impact on the field of nanotechnology, especially in the area of molecular electronics. Our basic research will contrib ....New metal-molecule binding motifs for self-assembled monolayers and nanodevices. The goal of this research is to investigate technologically interesting electronic materials using new molecular assemblies. We explore their application in some fundamental components of molecular electronic systems and anticipate that knowledge gained from our investigations will have significant impact on the field of nanotechnology, especially in the area of molecular electronics. Our basic research will contribute to Australia's reputation as a source of innovative research and ideas in an area where there is growing international momentum.Read moreRead less
Repulsive van der Waals forces and Brownian ratchet motors: manipulating thermal and quantum Fluctuations. A fundamental problem with miniaturizing machines and mechanical devices below the micron scale is the issue of friction and lubrication. One way to completely circumvent the need for lubrication is to use a little-studied phenomenon known as 'repulsive van der Waals forces', to create materials that fundamentally repel each other in certain fluid environments. This effect is very large at ....Repulsive van der Waals forces and Brownian ratchet motors: manipulating thermal and quantum Fluctuations. A fundamental problem with miniaturizing machines and mechanical devices below the micron scale is the issue of friction and lubrication. One way to completely circumvent the need for lubrication is to use a little-studied phenomenon known as 'repulsive van der Waals forces', to create materials that fundamentally repel each other in certain fluid environments. This effect is very large at the nanoscale and this proposal examines how such forces can be used to make 'lubricant free' motors and nanomachines. This will open up the possibility of building small and portable sensors, actuators, microfluidic devices and eventually active drug delivery systems for health applications.Read moreRead less
Self-Organised 3-D Arrays of Stimulus Responsive Block Copolymer Micelles. At the core of developments in nanotechnology is a desire to manufacture functional devices from molecular or colloidal building blocks. A significant component of this effort is directed at the self-assembly of these materials on solid substrates. Ultimately, the development of higher order functional nanomaterials requires a fine control over the 3-dimensional location of each component; this is a significant problem. I ....Self-Organised 3-D Arrays of Stimulus Responsive Block Copolymer Micelles. At the core of developments in nanotechnology is a desire to manufacture functional devices from molecular or colloidal building blocks. A significant component of this effort is directed at the self-assembly of these materials on solid substrates. Ultimately, the development of higher order functional nanomaterials requires a fine control over the 3-dimensional location of each component; this is a significant problem. In this project our aim is to develop novel self-assembled surface coatings using block copolymer micelles. Spatial control of the micelle adsorption at the solid-aqueous interface will give us a significant degree of control over molecular location in 3-dimensions.Read moreRead less
Materials World Network: Nanostructured Polymer Templating of Liquid Crystals. Liquid crystals have a range of technological applications, with the most successful being displays used in computers, watches and calculators. These applications are dependent on controlling the interfaces of liquid crystals. This project will combine the areas of liquid crystals and polymer adsorption for the preparation of a new class of intelligent nanomaterials with well-defined properties. These engineered mater ....Materials World Network: Nanostructured Polymer Templating of Liquid Crystals. Liquid crystals have a range of technological applications, with the most successful being displays used in computers, watches and calculators. These applications are dependent on controlling the interfaces of liquid crystals. This project will combine the areas of liquid crystals and polymer adsorption for the preparation of a new class of intelligent nanomaterials with well-defined properties. These engineered materials are of interest in industrial applications, including the development of chemical and biological sensors and drug delivery vehicles. This program also strengthens the ties between two world-class nanotechnology groups, capturing new opportunities in nanostructured materials.Read moreRead less
Preparation of nanostructured surfaces by electrochemical deposition through lyotropic liquid-crystal templates. Hexagonal-phase lyotropic liquid crystals may be used as templates to deposit metals on electrodes. The sizes of the structures made by this method are a few nanometres. We propose to exploit both the aqueous and non-aqueous parts of the liquid crystal to deposit different metals, polymers or metals and polymers. Thin metal wires (nano-wires) sheathed in polymer will be the thinnest i ....Preparation of nanostructured surfaces by electrochemical deposition through lyotropic liquid-crystal templates. Hexagonal-phase lyotropic liquid crystals may be used as templates to deposit metals on electrodes. The sizes of the structures made by this method are a few nanometres. We propose to exploit both the aqueous and non-aqueous parts of the liquid crystal to deposit different metals, polymers or metals and polymers. Thin metal wires (nano-wires) sheathed in polymer will be the thinnest insulated wires ever made. Carbon nanotubes will also be aligned in the hexagonal hole in the template allowing exploitation of these unique species. The structures that will be fabricated will be candidates for catalysts, sensor arrays and electronic devices.Read moreRead less
Material Properties of Nanocrystals. The mechanical characteristics of nanocrystals determine the viability of many novel applications and devices emerging from the field of nanotechnology. Despite their fundamental importance, the mechanical properties of these nanocrystals is only vaguely understood, because their size has prohibited their measurement. In this project, we shall investigate the mechanical properties of these materials for the first time using a combination of theoretical modell ....Material Properties of Nanocrystals. The mechanical characteristics of nanocrystals determine the viability of many novel applications and devices emerging from the field of nanotechnology. Despite their fundamental importance, the mechanical properties of these nanocrystals is only vaguely understood, because their size has prohibited their measurement. In this project, we shall investigate the mechanical properties of these materials for the first time using a combination of theoretical modelling, atomic force microscopy, and a new form of spectroscopy that allows the actual deformation of nanocrystals to be measured. The fundamental scientific knowledge gained is expected to impact on the development of current and future nanodevices.Read moreRead less
Nanocrystal Electronics: A Sol-Gel Approach. Australia is building capability in printable electronics, which will supersede traditional semiconductor fabrication methods. The main goals are to mass produce key electronic structures such as display devices, solar cells and sensors using cheaper, non-clean room based technologies via ink-jet printing and other high throughput methods. The integration of sol-gel based materials into roll-to-roll manufacturing will advance Australian manufacturing ....Nanocrystal Electronics: A Sol-Gel Approach. Australia is building capability in printable electronics, which will supersede traditional semiconductor fabrication methods. The main goals are to mass produce key electronic structures such as display devices, solar cells and sensors using cheaper, non-clean room based technologies via ink-jet printing and other high throughput methods. The integration of sol-gel based materials into roll-to-roll manufacturing will advance Australian manufacturing capabilities and generate new jobs in the rapidly growing printable electronics field.Read moreRead less
Salt, Bubbles and Life; A study of ion specificity in colloid science. A colloidal solution is a liquid that contains a finely dispersed material. The properties of these solutions are critical in many industrially important practices and in the everyday processes of life. Though not understood, it is observed that the type of salt in solution controls how the colloid behaves. Through a series of very careful experiments we seek to learn precisely how different salts influence the properties of ....Salt, Bubbles and Life; A study of ion specificity in colloid science. A colloidal solution is a liquid that contains a finely dispersed material. The properties of these solutions are critical in many industrially important practices and in the everyday processes of life. Though not understood, it is observed that the type of salt in solution controls how the colloid behaves. Through a series of very careful experiments we seek to learn precisely how different salts influence the properties of a colloidal solution. This world-leading research will enable us to improve our fundamental understanding of colloids and thereby facilitate advances in topics as diverse as enzymatic action and minerals purification, ensuring Australia remains at the forefront of science in this field.Read moreRead less
Engineered nanostructured materials via continuous polymer assembly for advanced bioapplications. The development of new and flexible processes is critical to the design and construction of advanced materials for future applications in nano- and biotechnology. This project will develop innovative and versatile "bottom-up" nanotechnology techniques to afford nanostructured materials with unprecedented properties. This project has the potential to revolutionise current approaches for forming surfa ....Engineered nanostructured materials via continuous polymer assembly for advanced bioapplications. The development of new and flexible processes is critical to the design and construction of advanced materials for future applications in nano- and biotechnology. This project will develop innovative and versatile "bottom-up" nanotechnology techniques to afford nanostructured materials with unprecedented properties. This project has the potential to revolutionise current approaches for forming surface coatings, films and advanced particles, leading to significant outcomes in diverse areas, including drug delivery, biomaterial implants and biocatalysis. The project will contribute to the development of a robust Australian nanotechnology industry, with the advanced materials developed expected to have health benefits for Australian citizens.Read moreRead less
Building Molecularly Engineered Polymer Nanomaterials. The development of new technologies at the interface between nano- and biotechnology promises to revolutionise healthcare and medicine. This research program will involve the design and synthesis of responsive and programmable polymers and their assembly to form next-generation, engineered materials. The nanomaterials prepared are expected to lead to the development of techniques that enable new types of minimally invasive diagnostics and th ....Building Molecularly Engineered Polymer Nanomaterials. The development of new technologies at the interface between nano- and biotechnology promises to revolutionise healthcare and medicine. This research program will involve the design and synthesis of responsive and programmable polymers and their assembly to form next-generation, engineered materials. The nanomaterials prepared are expected to lead to the development of techniques that enable new types of minimally invasive diagnostics and therapeutics as well as smaller devices. The interdisciplinary research program will cement Australia's position as a leading country in nanobiotechnology research and development.Read moreRead less