New Electron Field Emission Films Based on Aligned Carbon Nanotube Guests in Liquid Crystalline Polymer Hosts. This project seeks to develop a new class of electron field emitting nanocomposite consisting of nanotubes in liquid crystalline polymers. Electron emitting materials are in much demand in x-ray and microwave generation, computer displays and low-energy lighting. We utilise the ready alignability of liquid crystalline units in magnetic fields to cause realignment of incorporated carbon ....New Electron Field Emission Films Based on Aligned Carbon Nanotube Guests in Liquid Crystalline Polymer Hosts. This project seeks to develop a new class of electron field emitting nanocomposite consisting of nanotubes in liquid crystalline polymers. Electron emitting materials are in much demand in x-ray and microwave generation, computer displays and low-energy lighting. We utilise the ready alignability of liquid crystalline units in magnetic fields to cause realignment of incorporated carbon nanotubes, followed by polymer solidification to maintain orientation. It involves low temperature processing, contrasting very favourably with current problematic, high temperature processes. This allows materials to be cast on flexible polymer substrates, potentially enabling construction of cathode tubes to replace existing mercury-containing fluorescent lighting.Read moreRead less
Novel Nanofibre-Templated Nanotubes Prepared by Using ABA Block Copolymers. The aim of this project is to prepare new, highly functional nanomaterials using layer-by-layer assembly of polyelectrolytes on a three-dimensional template. Using this approach, a core-shell fibre is initially prepared by alternate deposition of oppositely charged materials onto an electrospun fibre template. The initial fibre can then be dissolved to give hollow nanotubes. New block copolymers, incorporating both charg ....Novel Nanofibre-Templated Nanotubes Prepared by Using ABA Block Copolymers. The aim of this project is to prepare new, highly functional nanomaterials using layer-by-layer assembly of polyelectrolytes on a three-dimensional template. Using this approach, a core-shell fibre is initially prepared by alternate deposition of oppositely charged materials onto an electrospun fibre template. The initial fibre can then be dissolved to give hollow nanotubes. New block copolymers, incorporating both charged and uncharged domains, will be used in the assembly, in order to design tubes with novel properties. The behaviour of these tubes under a variety of pH and solvent conditions will then be examined, and the tubes characterized using various microscopy techniques.Read moreRead less
Development of a molecular flash memory for long-term, extremely high-capacity, unpowered data storage. This collaborative project with INTEL will demonstrate an array of Flash-RAM molecular-memory cells capable, at room temperature, of storing a terabit of data on an area of 2 square mm. This data density is more than four orders of magnitude greater than any commercially available technology and unattainable by conventional silicon-based electronics. We will design and optimize the memory cel ....Development of a molecular flash memory for long-term, extremely high-capacity, unpowered data storage. This collaborative project with INTEL will demonstrate an array of Flash-RAM molecular-memory cells capable, at room temperature, of storing a terabit of data on an area of 2 square mm. This data density is more than four orders of magnitude greater than any commercially available technology and unattainable by conventional silicon-based electronics. We will design and optimize the memory cell, develop the synthesis method, synthesize arrays of the memory cells, and develop new molecular addressing technologies.Read moreRead less
Self-Assembled Porphyrin-Fullerene Photovoltaic Electrodes: Towards Nanostructured Organic Solar Cells. Energy is arguably the single most important problem facing humanity today. The development of cheap, efficient photovoltaic technology could dramatically change this, providing humanity with renewable, environmentally acceptable energy resources. The need to replace present electrical energy generation, largely based on fossil fuel, is without argument given the detrimental effects of global ....Self-Assembled Porphyrin-Fullerene Photovoltaic Electrodes: Towards Nanostructured Organic Solar Cells. Energy is arguably the single most important problem facing humanity today. The development of cheap, efficient photovoltaic technology could dramatically change this, providing humanity with renewable, environmentally acceptable energy resources. The need to replace present electrical energy generation, largely based on fossil fuel, is without argument given the detrimental effects of global warming from increasing carbon dioxide production. The development and implementation of cheap, efficient photovoltaic technologies in Australia will not only ensure its sustainable economic growth but also contribute in a major way to the improved use of land, water, mineral and other energy resources in Australia. Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0560679
Funder
Australian Research Council
Funding Amount
$932,870.00
Summary
Materials and Surface Characterisation Facility. Australian scientists are well positioned to be at the forefront of nanotechnology, biotechnology and advanced materials development. The proposed Facility, housing state-of-the-art equipment, will enable cutting-edge research in these areas by internationally renowned researchers at the University of Melbourne, Monash University, RMIT University, and CSIRO. Such research will facilitate the development of advanced materials for diverse applicatio ....Materials and Surface Characterisation Facility. Australian scientists are well positioned to be at the forefront of nanotechnology, biotechnology and advanced materials development. The proposed Facility, housing state-of-the-art equipment, will enable cutting-edge research in these areas by internationally renowned researchers at the University of Melbourne, Monash University, RMIT University, and CSIRO. Such research will facilitate the development of advanced materials for diverse applications including drug delivery, quantum computing, photonics and tissue engineering. The multi-user Facility will enable closer collaboration with researchers in academia and industry, and will be integral in training the next generation of Australian scientists in the nano- and biosciences.Read moreRead less
Multimodal biomedical imaging probes: development of advanced polymer nanocomposite devices for oncology. Despite significant research being directed toward cancer treatment, 7.6 million people died world wide in 2007. Early detection and treatment is widely recognised as being effective in significantly reducing mortality rates. Biomedical imaging techniques are routinely used for detection and staging of many cancers. However, greater sensitivity is required so that these techniques can be app ....Multimodal biomedical imaging probes: development of advanced polymer nanocomposite devices for oncology. Despite significant research being directed toward cancer treatment, 7.6 million people died world wide in 2007. Early detection and treatment is widely recognised as being effective in significantly reducing mortality rates. Biomedical imaging techniques are routinely used for detection and staging of many cancers. However, greater sensitivity is required so that these techniques can be applied to very early detection of tumours. To overcome this short-coming the next generation of imaging probes will be developed, which will require fundamental investigations in polymer and nanomaterials science to maximise imaging sensitivity and extend probe functionality. Successful outcomes will lead to significant benefits to healthcare in Australia.Read moreRead less
Controlled Macromolecular Architectures for Functional Nanomaterials Design. The research involves an exciting and innovative collaboration between two internationally recognized Australian research groups, cementing Australia's position as a leading country for research in polymer science and nanotechnology. Advanced polymer chemistry will be used to make ?smart? polymers that can controllably respond to changes in their surroundings. These will then be assembled to form materials with dimensio ....Controlled Macromolecular Architectures for Functional Nanomaterials Design. The research involves an exciting and innovative collaboration between two internationally recognized Australian research groups, cementing Australia's position as a leading country for research in polymer science and nanotechnology. Advanced polymer chemistry will be used to make ?smart? polymers that can controllably respond to changes in their surroundings. These will then be assembled to form materials with dimensions of the order of millionths of millimeters - forming so-called "smart nanomaterials". The materials prepared are expected to find application in the agricultural and pharmaceutical sectors, contributing to the well-being of Australian citizens and the development of a robust Australian industry.Read moreRead less
Development of a test bed for molecular memory and molecular photovoltaic devices. The development of nanostructured materials and the devices that utilize them is at the forefront of modern science and technology. Electrical devices whose functional units are structurally ordered single molecules dominate biochemical processes, especially pertinent ones being photosynthesis and cellular energy production; artificial devices promise new technologies in multi-$B markets such as long-term data st ....Development of a test bed for molecular memory and molecular photovoltaic devices. The development of nanostructured materials and the devices that utilize them is at the forefront of modern science and technology. Electrical devices whose functional units are structurally ordered single molecules dominate biochemical processes, especially pertinent ones being photosynthesis and cellular energy production; artificial devices promise new technologies in multi-$B markets such as long-term data storage and renewable solar-energy production. Interfacing molecules with macroscopic interconnects poses a great technological challenge, however, and in this project the underlying basic science will be determined through the formation of molecules into device-accessible functional materials.Read moreRead less
Radio-magnetic nanoparticles as bimodal positron emission tomography/magnetic resonance imaging contrast agents for dendritic cell tracking. Biomedical imaging is limited by a lack of commercial dual-mode contrast agents, which may be simultaneously used for magnetic resonance (MR) and positron emission tomography (PET) imaging. This project will develop a nanotechnology-based biocompatible dual-mode contrast agent for simultaneous PET and MR imaging, reducing associated side effects.
Advanced nanoparticle stabilisation and functionalisation: small particles with huge potential. Australia is strongly investing in nanotechnology and through the governments priority goals 'Frontier Technologies for Building and Transforming Australian Industries' it has been recognised as an important area for investment. This proposal will help develop an internationally recognised nano-industry. It is envisaged that the particles made during this work will have direct implications for the pub ....Advanced nanoparticle stabilisation and functionalisation: small particles with huge potential. Australia is strongly investing in nanotechnology and through the governments priority goals 'Frontier Technologies for Building and Transforming Australian Industries' it has been recognised as an important area for investment. This proposal will help develop an internationally recognised nano-industry. It is envisaged that the particles made during this work will have direct implications for the public - creating a new class of medical diagnostic particles with better resolution and specificity. These particles have the potential to diagnose patients more precisely and at an earlier stage than is currently available. Additionally, these particles could be designed to load drugs and hence could be used to treat diseases such as cancer.Read moreRead less