Fabrication and Application of Ion-Sensors Based on the Voltammetry of Nanocrystals Adhered to Electrode Surfaces. A significant need exists for the low cost determination of cations and anions in biologically (blood, urine), industrially (process streams) and environmentally (rivers, lakes) important fluids. In this project, skills in sensor design, scientific instrumentation, materials science, electrochemistry and analytical science provided by a consortium of scientists at Monash University ....Fabrication and Application of Ion-Sensors Based on the Voltammetry of Nanocrystals Adhered to Electrode Surfaces. A significant need exists for the low cost determination of cations and anions in biologically (blood, urine), industrially (process streams) and environmentally (rivers, lakes) important fluids. In this project, skills in sensor design, scientific instrumentation, materials science, electrochemistry and analytical science provided by a consortium of scientists at Monash University, the Victorian Institute for Chemical Sciences, Oxford Biosensors and Oxford University will be integrated to fabricate and develop applications of commercially viable ion-sensing systems. The principles to be utilised are based on novel forms of voltammetry of nanocrystals adhered to electrode surfaces.Read moreRead less
New Membrane Chips For Protein Interaction Analysis. This proposal is based on a strategic partnership between Monash University and Farfield Sensors. We will create a series of new biosensors that will be used to establish a new approach to the structural analysis of membrane protein function. In particular, this technology may lead to the identification of new proteins and drug targets for therapeutic development. The long-term outcome would be the development of improved therapeutics which wo ....New Membrane Chips For Protein Interaction Analysis. This proposal is based on a strategic partnership between Monash University and Farfield Sensors. We will create a series of new biosensors that will be used to establish a new approach to the structural analysis of membrane protein function. In particular, this technology may lead to the identification of new proteins and drug targets for therapeutic development. The long-term outcome would be the development of improved therapeutics which would be coupled to potential economic returns when further commercialisation is achieved. Read moreRead less
Nano-scale modification of gold surfaces for sensing mercury from gaseous effluents of alumina refineries. The Australian alumina industry contributes more than $5.4 billion export income annually. It is also a major driver of the rural economy with all but one of Australia's seven alumina refineries located in rural areas. In response to the industry's attempts to reduce the environmental impact of its processes, this project will conduct basic strategic research into the interaction between m ....Nano-scale modification of gold surfaces for sensing mercury from gaseous effluents of alumina refineries. The Australian alumina industry contributes more than $5.4 billion export income annually. It is also a major driver of the rural economy with all but one of Australia's seven alumina refineries located in rural areas. In response to the industry's attempts to reduce the environmental impact of its processes, this project will conduct basic strategic research into the interaction between mercury vapour and gold surfaces at the nano-level. Our principal aim is to develop mercury sensor technology suited to alumina refineries. This innovative technology will be a significant breakthrough in the control of mercury emissions and have many other applications.
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Adaptive aberration compensation in high refractive index materials for next-generation active microphotonic devices. The method proposed in this project is a very promising and versatile method to compensate the strong aberration in a high refractive index material. The successful compensation of such aberration will allow people to fabricate microdevices directly inside high refractive index materials. This project will greatly advance optical fabrication techniques and expand the national kno ....Adaptive aberration compensation in high refractive index materials for next-generation active microphotonic devices. The method proposed in this project is a very promising and versatile method to compensate the strong aberration in a high refractive index material. The successful compensation of such aberration will allow people to fabricate microdevices directly inside high refractive index materials. This project will greatly advance optical fabrication techniques and expand the national knowledge in the area of nonlinear PhCs (photonic crystals) and related applications. It is expected that the project will provide many chances for postgraduate students to be involved. In future, nonlinear PhCs and related devices may be widely used in daily life and this project may provide some opportunities for industry.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0561157
Funder
Australian Research Council
Funding Amount
$110,000.00
Summary
Multi-functional fluorescence microscopy laboratory. We have proposed a multipurpose fluorescent microscopy facility coupled to the RMIT microfabrication facility primarily for the study of the processes that make up lab-on-a-chip systems (the miniaturisation of a laboratory full of equipment to fit onto a credit card sized chip). Specifically the heart of the equipment, the variable wavelength pulsed laser coupled to an inverted microscope, will allow the study of temperature and fluid flow i ....Multi-functional fluorescence microscopy laboratory. We have proposed a multipurpose fluorescent microscopy facility coupled to the RMIT microfabrication facility primarily for the study of the processes that make up lab-on-a-chip systems (the miniaturisation of a laboratory full of equipment to fit onto a credit card sized chip). Specifically the heart of the equipment, the variable wavelength pulsed laser coupled to an inverted microscope, will allow the study of temperature and fluid flow in microchannels, the development of new electro-optic components, direct visualisation of electromagnetic radiation and its effect on cells, and the coupling of electrical and optical stimulation and sensing devices to microfluidic channels. Read moreRead less